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Intraoperative Mapping of Cognitive Networks Which Tasks for Which Locations Emmanuel Mandonnet Guillaume Herbet Editors
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Intraoperative Mapping of Cognitive Networks
Emmanuel Mandonnet • Guillaume Herbet Editors
Intraoperative Mapping of Cognitive Networks Which Tasks for Which Locations
Editors Emmanuel Mandonnet Department of Neurosurgery Lariboisière Hospital Paris Brain Institute (ICM) and Paris University Paris France
Guillaume Herbet Department of Neurosurgery Gui de Chauliac Hospital, Montpellier & Institute of Functional Genomics University of Montpellier, INSERM, CNRS Montpellier France
ISBN 978-3-030-75070-1 ISBN 978-3-030-75071-8 (eBook) https://doi.org/10.1007/978-3-030-75071-8 © Springer Nature Switzerland AG 2021 This work is subject to copyright. All rights are reserved by the Publisher, whether the whole or part of the material is concerned, specifically the rights of translation, reprinting, reuse of illustrations, recitation, broadcasting, reproduction on microfilms or in any other physical way, and transmission or information storage and retrieval, electronic adaptation, computer software, or by similar or dissimilar methodology now known or hereafter developed. The use of general descriptive names, registered names, trademarks, service marks, etc. in this publication does not imply, even in the absence of a specific statement, that such names are exempt from the relevant protective laws and regulations and therefore free for general use. The publisher, the authors, and the editors are safe to assume that the advice and information in this book are believed to be true and accurate at the date of publication. Neither the publisher nor the authors or the editors give a warranty, expressed or implied, with respect to the material contained herein or for any errors or omissions that may have been made. The publisher remains neutral with regard to jurisdictional claims in published maps and institutional affiliations. This Springer imprint is published by the registered company Springer Nature Switzerland AG The registered company address is: Gewerbestrasse 11, 6330 Cham, Switzerland
Foreword
With the exception of a few seminal works by pioneers in surgical brain mapping, such as Wilder Penfield and George Ojemann, the link between neurosurgery and basic neuroscience remained weak for about a century. The reinforcement of interactions across technical and conceptual advances in the understanding of dynamic processes underpinning neural functions, and clinical implications in brain-damaged patients, especially in those who need cerebral surgery, is now a reality. Remarkably, the emerging field of connectomics, which resulted in the elaboration of original models in cognitive neuroscience based upon intercommunications between distributed neural networks, and challenging the obsolete localizationist framework yet still entrenched in the neurosurgical and neurological communities, opened new avenues to explore neuroplastic mechanisms. Indeed, predicting potentials and limitations of neural redeployment at the individual level is very valuable to preserve an optimal quality of life in patients who will undergo brain surgery. Besides epilepsy, such an ambitious aim is particularly critical in neurooncology, since the life expectancy significantly increased in brain tumor patients in the past two decades, mainly due to early and extensive surgical resections. To this end, beyond the contribution of perioperative noninvasive functional neuroimaging, intra-surgical awake mapping by means of direct cortical and axonal electrostimulation, able to transitorily and repeatedly disrupt specific functional systems as well as their interplay, and combined with real-time behavioral monitoring, allows structural-functional correlations throughout the surgical act. The ultimate aim is to decipher the individual connectome and to tailor the resection according to the functional circuitry, most of the time already reorganized due to the prior tumor progression, in order to find the best compromise between the oncological and neurological aspects. In this connectome-based approach, awake surgery should be considered in a systematic way regardless of the tumor location. Therefore, an optimal selection of tasks to be administrated during the cognitive monitoring is of utmost importance, to optimize the extent of resection and thus survival while minimizing the functional risk. Importantly, such a selection must be based not only on the relationships between the tumor and the surrounding cortico-subcortical neural circuits but also on the definition of a personalized quality of life by the patient him/herself, taking into consideration his/her wishes as well as his/her environment. Making the link between patients’ expectations, neural foundations of behavior, and surgical planning implies first to revisit the traditional rigid and reductionist v
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model of brain organization which prevailed for too long, and which commonly led to a simplistic view in clinical practice, that is, to propose a battery of tasks according to the lobar cortical localization of a cerebral lesion. This is the reason why a textbook on intraoperative mapping of cognitive networks was desperately needed. Led by the editors, Emmanuel Mandonnet and Guillaume Herbet, this collective body of work will serve as a comprehensive book for all multidisciplinary neurosurgical teams with a flexible and individualized perspective of brain surgery. In fact, what makes this volume so unusual is its translational approach bringing together experts in various fields, including not only neurosurgeons but also neuropsychologists, speech therapists, neurologists, neuroanatomists, neurophysiologists, and neuroscientists. The philosophical positions the authors have taken in rethinking the neural bases sustaining functional networks, with a progression from unimodal segregated systems (as vision) to more integrated complex systems and their dynamic interactions in a meta-networking perspective (as creativity), as well as the implication for neurosurgical management are quite unique and innovative, to say the least. The book is organized in a logical and informative fashion, starting with chapters covering the neurobiology of sensorimotor and visuospatial functions and the application of such knowledge to select and administrate adapted tasks into the operating theater. I particularly like the way in which movement was redefined, that is, beyond the output pyramidal system that should be preserved to avoid postoperative hemiparesis in classical neurosurgery (usually performed under general anesthesia), as an interplay between networks mediating movement execution and movement control, making possible a mapping and monitoring of complex skills (as bimanual coordination) in awake patients who expressed their desire to preserve a perfect conation. The second part of the textbook is dedicated to various aspects of oral and written language, which still represents for the vast majority of neurosurgeons the optimal (or even the sole) indication of awake mapping. Yet, as demonstrated in the next chapters, higher-order cognitive functions have also to be considered, whatever the hemisphere involved by the lesion, including in the right side wrongly claimed as “nondominant” in the older literature. Besides nonverbal semantics and executive functions, an important issue is the introduction of tasks capable of providing during surgery insights into the theory of mind, which is critical for interpersonal relationships: this breakthrough goes beyond the classical view of a damaged brain taken in isolation, disconnected from its social environment. Another original concept is the multitasking throughout the resection, increasing the cognitive demand by playing with the inter-system communication without extending the duration of surgery, so taking account of the practical constraints in the operating room, especially the risk of patient tiredness. Finally, future prospects are discussed, paving the way for monitoring more integrated aspects of human being, such as personality, creative behavior, and intuition. These high-order considerations raise in fine indirectly the problem of the onco-functional balance, since the price to pay to optimize intraoperative mapping could be to interrupt prematurely the resection: such medico-surgical as well as philosophical discussion needs to take place in a systematic manner with the patient and his/her family before each surgery, to select tasks “à la carte.”
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Modern neurosurgery should play a pivotal role in developing the synapse between, on one hand fundamental neuroscience, by designing on the basis of factual observations new models of dynamic spatiotemporal integration within and across neural circuits underpinning constant plastic reconfiguration, and on the other hand clinical applications, by using such an instability of the connectome to increase survival of brain-damaged patients while preserving their conation, cognition, emotion, and adapted behavior—in order to give them the opportunity to make their own choices regarding long-term projects. I have no doubt that this comprehensive and unique textbook edited by Dr. Mandonnet, Dr. Herbet, and their colleagues will serve this purpose with considerable distinction. I applaud them for bringing everything known about this complicated subject, so far poorly explored, within the confines of one textbook, which will be the definitive source on this topic. This volume is a major contribution that will be significant in the history not only of neurosurgery and cerebral mapping but also of clinical neurology and neurosciences. This is a must-read for anyone in the field—and beyond! Hugues Duffau Department of Neurosurgery Gui de Chauliac hospital Montpellier University Medical Center Institute of Functional Genomics University of Montpellier, INSERM U1191 Montpellier France
Preface
In the first half of the twentieth century, Wilder Penfield was the first neurosurgeon to use, in a systematic way, cortical electrostimulation in awake patients with the aim of mapping functional areas surrounding an epileptogenic focus to be removed. In the years 1940–1950, together with his student Theodore Rasmussen, who was both neurosurgeon and neurologist, they depicted with great accuracy not only the well-known homunculus describing the topographical organization of the different parts of the body within the pre- and post-central sensorimotor areas but also other sensory areas such as auditory or visual cortex. They further provided a detailed mapping of associative temporal areas, the stimulation of which triggered complex cognitive phenomenon, like experiencing vivid memories. Later on, Penfield collaborated with neuropsychologists Donald Hebb and Brenda Milner, and they introduced in the mapping procedure several cognitive tasks like picture naming, writing, and reading [1]: the modern intraoperative cognitive monitoring was born. Following this line of clinical practice for epilepsy surgery, the neurosurgeon George Ojemann and the neuropsychologist Catherine Mateer further introduced new behavioral tasks, in an attempt to evaluate and preserve, in addition to naming, syntax and verbal working memory [2]. Moreover, Ojemann envisioned that brain tumor patients should also benefit from applying the principles of intraoperative brain mapping with electrical stimulation under awake conditions. In the early 1990s, he guided the first steps in the field of two of his young fellows, Mitch Berger and Hugues Duffau. Together, they completely renewed the field of surgical neurooncology: Mitch Berger clearly demonstrated the survival benefit of maximizing the resection [3], while Hugues Duffau pushed further the potentialities of functional preservation. Indeed, he extended the mapping to the white matter pathways [4] and he introduced, in collaboration with neuropsychologists, new cognitive tasks, such as the line bisection paradigm [5]. Almost 30 years later, awake surgery for brain tumors has considerably spread over the world and is firmly considered as the most reliable tool to guide the neurosurgeon in a maximally safe resection. What is meant by safe resection? The answer to this important question greatly evolved over time. At first, preserving motor and language functions was the main objective. Hence, in addition to the detection of stimulation-induced movements, picture naming was, and still is, the essential task to be monitored throughout the resection. But then, it became apparent that clinical and neuropsychological postoperative examinations revealed that sparing areas responsive at picture naming task ix
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did not prevent deterioration in other language and cognitive functions, such as reading, writing, speaking spontaneously, spatial awareness, mentalizing, attention, cognitive flexibility, inhibition, emotion recognition, and so on. In particular, Herbet and Duffau demonstrated the importance of mapping the right hemisphere [6], a tumor location for which many teams previously did not consider awake surgery. Following their pioneering work, different teams around the world started to introduce new tasks in order to monitor a variety of cognitive functions, with the good intention to improve overall cognitive outcome. However, because there is always the possibility that such tasks are introduced for addressing some purely scientific questions rather than for the direct benefit of patients [7], some rules should be kept in mind when choosing to use a new task intraoperatively. First, the necessity to preserve a specific function should be thoroughly discussed with the patient during the preoperative interview. The goal is to define with the patient which cognitive profile would allow him to enjoy his life. This cognitive profiling differs for a musician, an engineer, a school teacher, or a building worker. From this starting point, a set of tasks tapping into the cognitive functions to be preserved could be selected. This is something neurosurgeons are not well trained for. The help of neuropsychologists is already essential here and, in fact, our brief historical review clearly highlights that a successful awake surgery relies on the smooth collaboration within a neurosurgeon/neuropsychologist pair. The next step is to select, according to the location of the tumor, a limited number of tasks aimed to map the different neurocognitive networks invaded by or close to the tumor. This is an incredibly big challenge, because there are no simple structure-function mappings in the cognitive domain. The reasons for this are multiple and beyond the scope of this introduction, but we can briefly mention the three major ones: –– Efficient cognitive functioning results from the synchronized interaction of several spatially distant but connected areas. –– Such network-level organization exhibits an important interindividual variability. –– Network resilience to injury also greatly varies between individuals, as patients are unequal regarding neuroplastic potentialities. As the aim of this book is to give an extensive overview of our current state of knowledge regarding this crucial question, these three points will be repeatedly addressed in the course of the chapters. But here again, the dialog with the neuropsychologist is also essential: any deficit evidenced in the preoperative evaluation should act as a strong warning that the corresponding function is at risk and that it should be monitored intraoperatively. Noninvasive preoperative functional mapping (task-based and resting state fMRI, tractography, MEG, TMS, …) has also an important role to play, as it provides a means to partly account for interindividual variability. The most striking example is given by the preoperative identification of uncommon reversed lateralization of verbal and visuo-spatial hemispheres, an essential information to integrate in the selection of intraoperative tasks [8]. Ultimately, there still remain many unclear points, and it is our hope that the reading of our book will motivate new neurosurgeon/neuropsychologist pairs to shed some light on some of those, through a retrospective in-depth analysis of the
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data collected during their experience in perioperative mapping of cognitive networks. Paris, France Montpellier, France
Emmanuel Mandonnet Guillaume Herbet
References 1. Penfield W, Roberts L. Speech and brain mechanisms [Internet]. Princeton University Press, Princeton. 1959 [cited 2021 Jan 16]. Available from: https://press.princeton.edu/books/hardcover/9780691642635/ speech-and-brain-mechanisms 2. Ojemann G, Mateer C. Human language cortex: localization of memory, syntax, and sequential motor-phoneme identification systems. Science. 1979;205(4413):1401–3. 3. Berger MS, Deliganis AV, Dobbins J, Keles GE. The effect of extent of resection on recurrence in patients with low grade cerebral hemisphere gliomas. Cancer. 1994;74(6):1784–91. 4. Duffau H, Capelle L, Sichez N, Denvil D, Lopes M, Sichez J-P, et al. Intraoperative mapping of the subcortical language pathways using direct stimulations. An anatomo-functional study. Brain.2002;125(Pt 1):199–214. 5. Thiebaut de Schotten M, Urbanski M, Duffau H, Volle E, Lévy R, Dubois B, et al. Direct evidence for a parietal-frontal pathway subserving spatial awareness in humans. Science. 2005;309(5744):2226–8. 6. Herbet G, Duffau H. Revisiting the functional anatomy of the human brain: toward a meta-networking theory of cerebral functions. Physiol Rev. 2020;100(3):1181–228. 7. Mandonnet E, Herbet G, Duffau H. Letter: Introducing new tasks for intraoperative mapping in awake glioma surgery: clearing the line between patient care and scientific research. Neurosurgery. 2020;86(2):E256–7. 8. Mandonnet E, Mellerio C, Barberis M, Poisson I, Jansma JM, Rutten G-J. When right is on the left (and vice versa): a case series of glioma patients with reversed lateralization of cognitive functions. J Neurol Surg A Cent Eur Neurosurg. 2020;81(2):138–46.
Contents
Part I Sensorimotor and Visuo-Spatial Functions 1 Motor Control�������������������������������������������������������������������������������������������� 3 Lorenzo Bello, Christian F. Freyschlag, and Fabien Rech 2 Vision���������������������������������������������������������������������������������������������������������� 21 Philippe Menei, Anne Clavreul, Morgane Casanova, David Colle, and Henry Colle 3 Frontal Eye Fields�������������������������������������������������������������������������������������� 41 Guillaume Herbet 4 Spatial Cognition���������������������������������������������������������������������������������������� 59 Paolo Bartolomeo and Emmanuel Mandonnet Part II Language Functions 5 Lexical Retrieval���������������������������������������������������������������������������������������� 79 Sylvie Moritz-Gasser and Guillaume Herbet 6 Spontaneous Speech���������������������������������������������������������������������������������� 95 Djaina Satoer, Elke De Witte, and Olga Dragoy 7 Reading ������������������������������������������������������������������������������������������������������ 115 Ilyess Zemmoura, Emmanuel Mandonnet, and Laurent Cohen 8 Handwriting������������������������������������������������������������������������������������������������ 127 Franck-Emmanuel Roux, Mahamadou Niare, Fleur Céline van Ierschot, Jean-Baptiste Durand, Gabriele Miceli, and Jean-François Demonet 9 Repeating���������������������������������������������������������������������������������������������������� 143 Sylvie Moritz-Gasser 10 Syntax���������������������������������������������������������������������������������������������������������� 155 Ryuta Kinno, Edward Chang, and Angela D. Friederici 11 Naming: Nouns and Verbs������������������������������������������������������������������������ 171 Adrià Rofes and Bradford Z. Mahon xiii
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12 Verbal Short-Term Memory �������������������������������������������������������������������� 195 Costanza Papagno and Juan Martino 13 Proper Names Retrieval���������������������������������������������������������������������������� 207 Costanza Papagno and Carlo Giussani 14 Multilingual Naming���������������������������������������������������������������������������������� 219 Alejandro Fernandez-Coello, Santiago Gil-Robles, and Manuel Carreiras Part III Higher-Order Functions 15 Semantic Cognition������������������������������������������������������������������������������������ 235 Sylvie Moritz-Gasser and Guillaume Herbet 16 Inhibition���������������������������������������������������������������������������������������������������� 251 Jérôme Cochereau, Michel Wager, Marco Rossi, Antonella Leonetti, Tommaso Sciortino, Lorenzo Bello, and Guglielmo Puglisi 17 Set Shifting�������������������������������������������������������������������������������������������������� 273 Jérôme Cochereau, Martine Zandvoort, Thomas Santarius, and Emmanuel Mandonnet 18 Social Cognition ���������������������������������������������������������������������������������������� 287 Riho Nakajima, Masashi Kinoshita, Mitsutoshi Nakada, and Guillaume Herbet 19 Multiple Tasks�������������������������������������������������������������������������������������������� 307 Henry Colle, Barbara Tomasino, Erik Robert, Miran Skrap, and Tamara Ius Part IV Prospects 20 Creativity���������������������������������������������������������������������������������������������������� 337 Théophile Bieth, Alizée Lopez-Persem, Marcela Ovando-Tellez, Marika Urbanski, and Emmanuelle Volle 21 Raising the Question of Personality Changes in Glioma Surgery �������� 355 Anne-Laure Lemaitre, Gilles Lafargue, and Guillaume Herbet 22 Patients with Barriers of Communication���������������������������������������������� 367 Sandro M. Krieg, Sebastian Ille, and Matthieu Delion 23 Inner Speech Brain Mapping. Is It Possible to Map What We Cannot Observe?���������������������������������������������������������������������� 381 Antoni Rodriguez-Fornells, Patricia León-Cabrera, Andreu Gabarros, and Joanna Sierpowska 24 Beyond Task: When Experience Shapes Intuition���������������������������������� 411 Hugues Duffau
Part I Sensorimotor and Visuo-Spatial Functions
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Motor Control Lorenzo Bello, Christian F. Freyschlag, and Fabien Rech
1.1
Neural Basis of Motor Control
Surgical mapping and tumor removal require a good understanding of the cortical and subcortical organization of the motor control network. To this end, we will review here the main components which might be considered during surgery. The primary motor cortex (M1), classically considered as the core of the motor system, is located on the lateral and medial face of the precentral gyrus and is constituted by Brodmann area 4 [1], containing pyramidal cells, from which emerge the “pyramidal” tract. This fascicle is going through the posterior limb of the internal capsule, decussates (for 80–85% of the fibers [2]) in the brainstem, and finally projects in the spinal cord, where it has the main control on the motoneuron of the IX couch of Rexed [3]. It presents a broad somatotopy [4], with region dedicated to the face and upper limb located laterally and region dedicated to the lower limb located medially. However, this classical view of the Penfieldian homunculus needs to be nuanced because there are many overlapping (up to four parts of the body) on the precentral gyrus [5]. In fact, the functional organization of the primary motor cortex is likely more oriented toward the goal of action and the precentral gyrus should be analyzed in terms of ethological action map rather than somatotopic map [6]. L. Bello Neurosurgical Oncology Unit, Department of Oncology and Hemato-Oncology, Università degli Studi di Milano, Milan, Italy e-mail: [email protected] C. F. Freyschlag Department of Neurosurgery, Medical University of Innsbruck, Innsbruck, Austria e-mail: [email protected] F. Rech (*) Service de Neurochirurgie, Université de Lorraine, CHRU-Nancy, Nancy, France Université de Lorraine, CNRS, CRAN, Nancy, France e-mail: [email protected] © Springer Nature Switzerland AG 2021 E. Mandonnet, G. Herbet (eds.), Intraoperative Mapping of Cognitive Networks, https://doi.org/10.1007/978-3-030-75071-8_1
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Immediately anterior to the precentral gyrus are located the dorsal (PMd) and ventral (PMv) premotor cortex, corresponding to Brodmann area 6. Both regions show strong connections with the supplementary motor area (SMA), M1, the spinal cord, and the superior (PMd) and inferior (PMv) parietal lobule [7, 8] in the framework of a large frontoparietal network. The PMd extends over the superior and middle frontal gyrus. The rostral PMd is involved in executive function, attention, and working memory whereas caudal PMd could be more dedicated to movement preparation and execution [9]. The PMd seems to be involved in decisional process during movement selection based on arbitrary clues [10, 11] and codes the conditional probability of a movement based on the body position to preselect the optimal motor program [12] probably thanks to dense connections with the superior parietal lobule through the superior longitudinal fascicle branch I (SLF I) [13]. fMRI studies reported a more complex functional segregation of the PMd, especially between working memory, attention, motricity of hand, eye movement, and action [14, 15]. The PMv is located on the ventral part of the precentral gyrus. By virtue of its connection to the inferior parietal lobule via the SLF III [13], its role is to adapt the hand shape to the object to favor the grasp contrary to the PMd which is involved in reaching [11]. Functional imaging studies suggest that the PMv is at least divided in two subregions activated, respectively, during spatial location (dorsal part of the PMv) and grasping observation (ventral part of the PMv). It is then one crucial component of the mirror neuron network [16]. Left PMv has also been identified as a crucial part of the speech network [17]. PMd and PMv over the precentral gyrus play a role in motor control as direct stimulations can elicit movement arrest emphasizing the role of such areas in motor control [18] (Figs. 1.1, 1.2, and 1.3). Recent studies based on direct electrical stimulation (DES) suggest that the precentral gyrus can be divided in several parts as proposed by neuroimaging studies (Fig. 1.4) [19]. Interestingly, three of these subareas are responsible of identical clinical responses during DES, thus excluding a simple somatotopic distribution of the network involved in motor control and reinforcing the hypothesis of ethological organization. Moreover, both hand movement and speech can be disturbed during single electrostimulation over both PMv and PMd, pleading in favor of a complex organization and interactions between the language and the motor networks at this level [20]. The SMA is located on the medial face of the brain on Brodmann area 6. It is classically divided into a rostral preSMA and a caudal SMAproper [21] although the cellular organization plead more for a continuum without sharp borders [22]. The SMA is connected to the alpha motor neuron of the spinal cord, the inferior frontal gyrus (IFG), PMd, PMv, M1, and superior (SPL) and inferior (IPL) parietal lobules [7, 23, 24]. Patterns of connections between the preSMA and the SMA proper are slightly different. PreSMA has connections with cognitive areas whereas SMA proper has only connections with motor and premotor area [24]. A somatotopic organization has been identified into the SMAproper with, rostrally to caudally, language in the dominant hemisphere, then face, upper limb, and finally lower limb area [25]. PreSMA is involved in internally generated movement [26] and the complex preSMA/SMAproper is involved in complex sequences of movements as
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Fig. 1.1 Overlap between negative motor (NMR) and positive motor (PMR) responses. Yellow dots = NMRs; red dots = PMRs. Top = face & speech; bottom = upper limb. The coordinates correspond to the MNI reference space (with permission of [19])
well as in temporal sequencing [27, 28], bimanual coordination [29], learning [30], task switching [31], and inhibition [24]. Given the putative numerous roles of the SMA, it has been suggested it is working through action-condition associations where motor behaviors are selected thanks to rules depending on conditions and requiring inhibition to select the appropriate sequences. Learning would then consist in creating the optimal action-condition associations. Under this view, the SMA should be considered as a whole and a continuum linking cognitive areas to motor ones thanks to action-condition associations [24]. These hypotheses tend to be confirmed by electrostimulation procedures which, despite a broad somatotopy, failed to identify sharpened borders into the SMA [32]. The SMA is connected with the IFG and the ventral part of the precentral gyrus through the frontal aslant tract (FAT). DES of the left and right FAT can induce speech arrest and surgery to the contact of the left FAT is followed by spontaneous speech disorders, confirming the role of this network in the speech initiation and
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Fig. 1.2 Probabilistic map of face/speech arrest negative motor responses for each hemisphere. The color bar indicates the probability. Scales were adjusted for each hemisphere, to highlight differences inside the precentral gyrus (with permission of [19])
Fig. 1.3 Probabilistic map of upper limb negative motor responses for each hemisphere. The color bar indicates the probability. Scales were adjusted for each hemisphere, to highlight differences inside the precentral gyrus (with permission of [19])
verbal fluency in the left hemisphere [33, 34]. SMA, PMd, and PMv are connected to the caudate nucleus through the frontal-striatal tract (FST). DES of the FST elicits movement arrest of the contralateral upper and lower limb, but also of bimanual movement and a reduction in verbal fluency (observed at the contact of the left FST) [33]. A somatotopic organization of the fibers subserving motor control has also been identified thanks to DES. Indeed, it is possible to disturb the ongoing movement (by inducing usually a movement arrest without loss of tone or consciousness—a so-called negative motor response [18]) of the lower limb posteriorly, medially, and superiorly, very close to the SMAproper (Fig. 1.5d) while site eliciting movement arrest of the upper limb is located more laterally, ventrally, and anteriorly (Fig. 1.5b). Between those sites are found site eliciting bilateral upper limbs arrest during a unilateral single DES (Fig. 1.5c). Finally, sites eliciting
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Fig. 1.4 Clusters of negative motor responses involving speech and upper limb (in blue). Each figure (a–e) represents the ispi- and contralateral connections on the lateral and medial faces of the hemispheres. Area connected structurally to the cluster with a probability superior to 95% are shown in red-yellow gradient. It is then possible to see how each cluster shares common connected area and conversely how cortical area is connected to several clusters. (c–e) Show three clusters over the precentral gyrus. The central cluster (e) includes connections of both dorsal and ventral clusters (c, d). Data about clusters are coming from Rech et al. (2019) (with permission of [20])
movement arrest of the face or speech are located the most anteriorly, laterally, and ventrally (Fig. 1.5a) [35, 36]. Despite an apparent dispersion of those sites, they are always located in a somatotopic manner at the individual level. The distribution of each kind of sites shows the orientation of the fibers subserving motor control, going from the premotor area to the head of the caudate nucleus and corresponding
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a
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Fig. 1.5 Repartition of sites eliciting negative motor responses (NMR) according to the kind of NMRs observed. All sites have been reported on a single side for a better visual appreciation. Each dot corresponds to a site of NMR (n = 18 patients). Axial, coronal, and sagittal views (with and without ipsilateral brain) are shown on each row. Each column corresponds to a single kind of NMRs. First column (a) with yellow dots: face/speech. NMR. Second column (b) with blue dots: contralateral upper limb NMR. Third column (c) with white dots: bilateral NMR. Fourth column (d) with red dots: lower limb NMR. Spatial distribution between each kind of NMR can, therefore, be analyzed for each plane (with permission of [35])
to the FST. As the FAT is slightly more anterior and lateral than the FST, sites of speech arrest/face are more likely due to FAT stimulation [33]. Such area as PMd, PMv, SMA, and M1 are strongly connected through U-fibers [37]. Association fibers such as the SLF I, II, and III connect the SPL, intraparietal sulcus (IPS), and IPL to the PMd and PMv and play a role in motor control as revealed by subcortical DES in the parietal lobe which can inhibit or accelerate contralateral body parts or both hands [38]. Interestingly, cortical
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terminations of each fascicle are overlapping and highlight the middle part of the precentral gyrus where numerous projections seem to converge, even from the arcuate fascicle (Figs. 1.4e and 1.6) [39, 40]. This region has been recently considered as an important hub for motor awareness as stimulation makes the patient unconscious of a DES-related motor arrest [41]. Conversely, each subpart of the precentral gyrus shares frontal and parietal connections with other subparts (Figs. 1.4 and 1.6). Such findings, and especially those revealed by DES, are in favor of a complex functional organization of cortical areas and tend to confirm that terms like PMd, PMV, SMAproper, and preSMA are too restrictive to apprehend the complexity of motor functions. At a subcortical level, the complex organization of the white
Fig. 1.6 Networks involving motor control and cortical connections. Clusters of negative motor responses are identified by black solid line over the preCG. Colors of the clusters correspond to the parietal origin of fibers. A gradient inside the preCG appears and is consecutive to a dorsoventral progressive modification of the connectivity, from the SLF I (yellow), the SLF II (blue), and finally the SLF III (red). Cortical terminations of the AF are also shown with black crossed lines up to the lower part of the dorsal cluster. The frontoparietal stream and its dorsoventral organization and overlapping are visible and allow to understand the segregation inside the precentral gyrus as well as the complex connectivity of the precentral gyrus with the frontal and the parietal lobe. SFG superior frontal gyrus, MFG middle frontal gyrus, SPL superior parietal lobule, IPS intraparietal sulcus, IPL inferior parietal lobule, MTG middle temporal gyrus, ITG inferior temporal gyrus, SLF superior longitudinal fasciculus, IFOF inferior fronto-occipital fasciculus, AF arcuate fasciculus, FAT frontal aslant tract (adapted with permission of [20])
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matter under the precentral gyrus has been well described [37] but exploring this region with DES remains difficult as the surgical approach to the precentral gyrus is limited anteriorly by fibers of the FST and the FAT and posteriorly by somesthetic fibers.
1.2
eview About Evidence of Long-Term Deficits R in Patients Who Did Not Benefit from Intraoperative Monitoring of Motor Control
Avoidance of motor deficits is probably one of the most relevant concerns in brain tumor surgery, above all when tumor involves primary motor cortex and its descending fibers. Such a concern is in fact based on evidence showing that resection of tumors located within M1 or near the corticospinal tract can produce postoperative motor deficits from 2% up to 30% of patients [42–46]. Although in most of the cases, when an EMG/MEPs monitoring is used, such deficits are not permanent and tend to recover during the first 3 months, developing new protocols to shorten this transient period of deficits and limit their functional impact remains an important surgical concern. Importantly, recent retrospective analysis [46] of patients operated for glioma located to approximately 2 cm from the precentral and postcentral sulcus demonstrated that despite the intraoperative neurophysiological mapping routinely used in brain tumor resection appears to be a good tool to preserve basic motor functions (i.e., the general ability to move arms and/or hands), difficulties in programming and execution of complex action or fine movements are often reported postoperatively by patients. Crucially such subtle difficulties can negatively affect the patients’ quality of life [47]. Taken together these data suggest that the standard approach, although efficient in most tumors involving M1 originating fibers, may have important limitations. When used in case of tumors involving the premotor or the parietal areas, the preservation of M1 and its originating fibers may be not enough to preserve motor function. This is due to the role of non-primary motor areas in performing and adapting movement to the action’s goal and to the relevance of the subcortical neural network connecting these cortical areas as previously described. Therefore, while M1 and its descending fibers are identified by DES without the need of patient’s collaboration, structures involved in higher level of motor programming and movement control (PMd, PMv, and SMA) can be mapped only while the patient is performing an ongoing motor task, in awake conditions.
1.3
eview About Knowledge Gained R from Lesion-Symptom Mapping
While the effect of M1 lesion in producing severe paralysis or complete paresis has been clear for almost a century, the role of non-primary motor cortices in high-level motor programming has been described more recently. Specifically, lesion mapping
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studies of apraxia, i.e., the inability to perform voluntary complex movement induced by neurological lesions in the absence of primary sensory or motor disorders, suggest the involvement of parietal and frontal regions (PMd, PMv, and SMA) [48–55]. Notably the two main classifications of apraxia, namely ideomotor apraxia (inability to imitate gesture of a model) and ideational apraxia (inability to perform pantomime without visual model), were disentangled in human through lesionsymptom mapping suggesting that areas specifically related to posterior IPS and SPL were more strongly associated with imitation. Conversely, pantomime deficits were associated with regions such as the supramarginal gyrus, the middle temporal gyrus, and the extreme capsule [56]. Together with these studies mainly pointing at a distributed cortical network, recently growing evidence has also highlighted the fundamental role of the white matter fibers connecting the abovementioned regions [57]. Specifically, the connections between the inferior parietal regions and the premotor cortex seem to play a crucial role. In monkeys and humans, this circuit was recently defined as the “lateral grasping network,” and demonstrated to be specifically active during hand movement in light and in darkness, pointing to its crucial role in hand tool manipulation even in a haptically driven context [58–60].
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eview of the Different Tasks Newly Designed R to Monitor Motor Control Intraoperatively
Standard motor monitoring using continuous MEPs/EMG recording is nowadays a mandatory and highly efficient protocol for the identification of motor sites in patients with tumors in descending motor pathways [44, 61, 62]. However, as mentioned before, when tumors are located at “distant” location from the central sulcus, yet involving relevant sensorimotor network areas (premotor or parietal regions), the standard approach requires the addition of supplemental higher order motor tasks in awake conditions. To date two main cognitive-motor tasks are routinely applied to monitor sensory motor integration and praxis. The simplest is to ask the patients to continually perform a repetitive voluntary movement of the upper limb (flexion-extension of the harm or finger-to-thumb task), and to observe the interferences generated by DES during the task performance [35, 63, 64]. This identifies all cortical and subcortical sites producing a modulation (i.e., an acceleration, slowdown, or interruption) of the ongoing movement. A second, recently developed task is the hand-manipulation-task (hMT) [46]. The patient is asked to perform a rotational movement on a tool shaped like a screwdriver. Although both approaches are similar, the latter requires a higher level of dexterity and haptic not visually guided interaction with an object, introducing in the motor task the investigation of the sensory-motor integration, a crucial component of motor control [65]. From a surgical viewpoint, specific patterns of interference on task execution (both behavioral and EMG) were associated with different parieto-frontal positive areas, providing surgeons with a highly specific tool to navigate within the praxis network: the M1 block is characterized by tonic muscle activation, the S1 by clonic twitches and release of the object, and the SMG and vPM by the arrest of movement without
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muscle activation. Moreover, the stimulation of the dorsomedial sectors of the premotor cortex induced a slow deceleration of the movement and a loss of rhythmicity in the hand–object interaction [46].
1.5
eview of Studies Evidencing a Functional R Improvement in Series of Patients Operated on With Versus Without Motor Control Monitoring
Cortical and subcortical brain mapping under awake or asleep conditions remain the gold standard of functional guided brain tumor resection. The authors are not aware of any study published that compared in a randomized fashion brain mapping to no functional guidance at all. However, there are centers that do not rely on mapping techniques during the resection of a potentially eloquent brain tumor. Magill et al. [44] analyzed 49 patients undergoing resections of tumors located primarily within the motor cortex. Awake craniotomy was performed in 65% of cases using standard neurophysiological monitoring and active hand/limb movement, while 35% were done under general anesthesia. The mean extent of resection was 91%. New or permanent postoperative motor deficits occurred in 20 patients. Of the permanent deficits, 14 were mild, 4 were moderate, and 2 were severe (3.8% of cases). A matched case-control study by Gerritsen et al. [66] compared awake brain mapping with no surgical adjunct technologies. Not only the extent of resection was significantly increased under awake and mapping conditions (94.9% vs. 70.3%), but the rate of postoperative complications was generally lower in the awake mapping group. In their large series of insular gliomas, Simon et al. [67] described their experience in a cohort of 94 consecutive patients. Their protocol of resection comprised a microsurgical (mostly transsylvian) approach with electrophysiological monitoring (MEP) resulting in a 13% rate of permanent hemiparesis. These results confirm that monitoring the primary motor pathway with MEPs technique is not enough to avoid permanent motor deficit. Martino et al. [64] reported a series study with 21 patients operated under awake procedure for removal of frontal tumors located in the superior frontal gyrus. The motor mapping procedure required the patients to perform different motor tasks (fingers-to-thumb opposition and bimanual alternate flexion and extension of the two hands). In the immediate postoperative period, 12 out of 21 showed a limb motor worsening, while at 3–6 months after surgery only 4 patients showed worsened performances compared with preoperative phase. Interestingly, only cortical mapping was used to find motor control disturbances and subcortical mapping was only used to monitor the pyramidal pathway explaining probably the rate of permanent deficit even if patients were operated awake (as subcortical fibers subserving motor control were removed (Fig. 1.5)). Using a similar approach, Gabarrós et al. [63] studied 15 patients with tumors infiltrating the premotor cortex. All patients were operated under awake conditions. While primary motor cortex was identified
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with DES, the SMA was mapped asking the patients to perform a classical contralateral finger opposition motor task. At 6 months follow-up, five patients showed permanent deficits interfering with daily life activities. These results confirm that assessing movement during surgery improves results but shows also that a cortical mapping of active motor function is not sufficient to prevent permanent deficit. Finally, in a study of low-grade glioma invading the SFG, it has been shown that preservation of the motor control fibers during an active motor task in awake surgery leads to no permanent deficit whereas identification and resection of such fibers for oncological purposes up to the pyramidal pathway lead to a SMA syndrome and to permanent deficit in bimanual coordination and motor control [68]. In a recent study authors investigated the efficacy of a novel task requiring hand–tool interaction (hMT) by comparing the incidence of postoperative ideomotor apraxia (immediate and 1 month after surgery) between patients undergoing the standard motor mapping with (n = 79) and without (n = 41) the hMT [46]. Crucially, the task dramatically reduced the incidence of postoperative ideomotor apraxia (global incidence 2.5% when the task was used in comparison with 50% when it was not applied) and the need of postoperative rehabilitation. These results finally confirm that preservation of cortical and subcortical structure involved in motor control is crucial to prevent permanent motor deficit in motor and premotor regions.
Illustrative Case (Fig. 1.7)
30-year-old woman presenting a tumor of the superior frontal gyrus evoking a low-grade glioma and revealed by seizure (a–d: pre- and postoperative MRI T2 FLAIR sequences). Decision to proceed to a tumor resection under awake condition to map language as well as motor control networks. e: results of the cortical mapping with 1 and 2: contraction of the upper limb, 3: contraction of the face and motor seizure of the face, 4: speech arrest, 5 slowdown of the speech and upper limb and motor arrest of the hand (negative motor response), 6 semantic paraphasia. (f) Results of the subcortical mapping with 8 corresponding to movement arrest of the upper limb and acceleration of the counting very close to the midline. Retractor shows the ventricle, which is widely opened, exposing the head of the caudate nucleus (smooth and white above the retractor). g–j: tumor cavity (blue) overlapped on a brain MNI 152 template with white matter fascicles coming from Rojkova’s atlas [69]. FAT (red) and FST (green) are shown. FAT is more anterior than FST, explaining why it is usually a limit posteriorly and laterally during resection (at the level of the tip of the retractor usually). In this case, it is interesting to note that tag 8 corresponds likely to both termination of the FAT and FST because the protocol consisted in asking the patient to count and move, in order to detect for disturbance in motor control of the speech and upper limb.
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Fig. 1.7 (continued)
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Conclusion
Taken together these data suggest that MEPs/EMG motor monitoring, mainly performed in asleep conditions, can be effectively complemented with active (awake condition) motor tasks (complex movement or interaction with tools) for resection of tumor located in premotor and parietal regions. It also shows that cortical and subcortical mapping of motor control are mandatory to preserve the motor control network and avoid permanent deficit. Such approach can help the neurosurgeon not only to preserve basic motor function but also higher order motor skills with a significant improvement of quality of life.
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65. Glencross DJ, Piek JP (eds) Motor control and sensory motor integration: issues and directions. Elsevier, Amsterdam; New York. 1995. 66. Gerritsen JKW, Viëtor CL, Rizopoulos D, Schouten JW, Klimek M, Dirven CMF, Vincent AJ-PE. Awake craniotomy versus craniotomy under general anesthesia without surgery adjuncts for supratentorial glioblastoma in eloquent areas: a retrospective matched case- control study. Acta Neurochir. 2019;161:307–15. 67. Simon M, Neuloh G, von Lehe M, Meyer B, Schramm J. Insular gliomas: the case for surgical management. J Neurosurg. 2009;110:685–95. 68. Rech F, Duffau H, Pinelli C, Masson A, Roublot P, Billy-Jacques A, Brissart H, Civit T. Intraoperative identification of the negative motor network during awake surgery to prevent deficit following brain resection in premotor regions. Neurochirurgie. 2017;63:235–42. 69. Rojkova K, Volle E, Urbanski M, Humbert F, Dell’Acqua F, Thiebaut de Schotten M. Atlasing the frontal lobe connections and their variability due to age and education: a spherical deconvolution tractography study. Brain Struct Funct. 2016;221:1751–66.
2
Vision Philippe Menei , Anne Clavreul, Morgane Casanova, David Colle, and Henry Colle
2.1
Introduction
At the first glance, mapping of the vision seems to be an easy task! In reality, it is as challenging as for the most complex cognitive functions. This is due to the very wide domain covered by the word “vision.” Vision is the perception of the surrounding environment using light in the visible spectrum reflected by the objects in the environment. The spatial array of the environment available to perception is called the visual field (VF). Visual perception is different from visual acuity, which refers to how clearly a person sees. The major difficulty in visual perception is that what people see is not simply a translation of retinal stimuli. Indeed, vision initiates several cognitive intricate functions, difficult to dissociate in the everyday life. Among them: • The neural mechanisms underlying stereo vision, motion perception, and color vision. P. Menei Department of Neurosurgery, Teaching Hospital, Angers, France CRCINA, UMR 1232 INSERM/CNRS, Angers, France Department of Neurosurgery, University of Angers, CHU Angers, CRCINA, Angers, France e-mail: [email protected] A. Clavreul Department of Neurosurgery, University of Angers, CHU Angers, CRCINA, Angers, France e-mail: [email protected] M. Casanova Rennes Institute of Electronics and Telecommunications, FAST Team (Facial Analysis Synthesis and Tracking) UMR CNRS, Centrale Supélec, Rennes, France D. Colle · H. Colle (*) Department of Neurosurgery, St Lucas General Hospital, Ghent, Belgium e-mail: [email protected] © Springer Nature Switzerland AG 2021 E. Mandonnet, G. Herbet (eds.), Intraoperative Mapping of Cognitive Networks, https://doi.org/10.1007/978-3-030-75071-8_2
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• Visual cognition, often associated with high-level vision and top-down visual processing, allowing constructing visual entities by collecting perceived parts into coherent wholes, determining which parts belong together [1]. • Visuospatial cognition referring to the ability to identify, integrate, and analyze space and visual form, details, structure in more than one dimension. All of these are essential for visuospatial skills and visuospatial working memory. • Object, face, emotion and word recognition, reading [2–5]. • Visual attention embracing many aspects, including spatial attention which allows to selectively process visual information through prioritization of an area within the visual field, but also object-based attention and social attention [6]. • The social vision belonging to social cognition, strongly itself linked to the previous described attention and visuospatial cognition. Vision plays a critical role in the development and maintenance of social exchange. The human visual system is particularly attuned at processing social cues, allowing “reading” others’ mental and emotional states and making snap judgments about their characters and dispositions. The gaze plays a major role in all these processes. The mapping of these last cognitive functions is specifically discussed in other chapters of this book (see Chaps. 4 and 18). The present one will be focused on a primary aspect of the vision, the VF, but necessarily, other complex visual functions will be addressed.
2.2
Neuroanatomy of the Visual System
The anatomy and physiology of the neural visual system are complex, though more and more understood [7]. The neural visual system is constituted by the photoreceptive cells in the retina, also known as the rods and cones, which detect the photons of light and respond by producing neural impulses. The cones which are specialized for maximum visual acuity are centered in a retinal area called fovea. The fovea is employed for accurate vision in a small region in the center of the VF. Common wisdom holds that, vision outside the fovea is severely impoverished. We know now that peripheral vision can provide useful information, peripheral acuity, and color vision. Nevertheless, color perception is best in the fovea and declines in the periphery. Sensitivity to red-green color variations declines more steeply toward the periphery than sensitivity to luminance or blue-yellow colors [8]. Extensive work in the past years has shown that observers can perform many recognition tasks with short presentation times that preclude multiple fixations. This includes object recognition, scene perception, recognition of social actions and face, and emotion perception [9, 10]. The retinal signals are transmitted by the optic nerve. The optic nerves from both eyes meet and cross at the optic chiasm. At this point the information coming from both eyes is combined and then splits according to the VF. The corresponding halves of the field of view (right and left) are sent to the left and right halves of the brain, respectively, to be processed (Fig. 2.1).
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Left visual field
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Fig. 2.1 Anatomy of the visual system and visual field defect function of the lesion site
From optic chiasm, information from the right visual field travel in the left optic tract, those from the left visual field travels in the right optic tract. Each optic tract terminates in a sensory relay nucleus in the thalamus of the brain: the lateral geniculate nucleus (LGN). In fact, the LGN is not just a simple relay station but it is also a center for processing. It receives reciprocal input from the cortical and subcortical layers and reciprocal innervation from the visual cortex. The neurons of the LGN then relay the visual information to the cortex through a pathway of white matter fibers: the optic radiations (OR). There is one such tract on each side of the brain, each one including an upper and a lower division. Depending on the level of a transection, a specific visual field defect will appear (Fig. 2.1). The right side of primary visual cortex deals with the left half of the VF of both eyes, and similarly for the left brain. A small region in the center of the field of view, the foveal vision, is processed redundantly by both halves of the brain.
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The LGN sends signals to primary visual cortex, also called V1 or striate cortex. It creates a bottom-up saliency map of the visual field to guide attention or eye gaze to salient visual locations. From this primary visual cortex, visual information is secondarily processed in the visual association cortex also called extrastriate cortex, which include the cortical area V2, V3, V4, and V5/MT [11]. As visual information passes forward through the visual hierarchy, the complexity of the neural representations increases. Whereas a V1 neuron may respond selectively to a line segment of a particular orientation, neurons in the lateral occipital complex respond selectively to complete object, and neurons in visual association cortex may respond selectively to human faces, or to a particular object. Recent descriptions of visual association cortex describe a division into two functional pathways, a ventral and a dorsal pathway. This conjecture is known as the dual streams hypothesis [12]. The dorsal stream, commonly referred as the “where” pathway, is involved in spatial attention. The ventral stream, commonly referred as the “what” pathway, is involved in the recognition, identification, and categorization of visual stimuli. However, there is still much debate about the degree of specialization within these two pathways, since they are in fact heavily interconnected. Lesion of primary visual cortex, as OR, leads to a contralateral homonymous hemianopia or quadrantanopia. Bilateral lesions can cause complete cortical blindness and can sometimes be accompanied by a condition called Anton-Babinski syndrome, which is when a patient is blind but denies having any visual deficit. In the area called the sagittal stratum which connects the occipital lobe to the rest of the brain, OR are anatomically close to other white matter fascicles [13–16]. These fascicles are particularly close at the level of the atrium of the lateral ventricle, where they are ordered from the surface to the ependyma: U fibers, arcuate/ superior longitudinal fascicle complex, vertical occipital fascicle, middle and inferior longitudinal fascicles, inferior fronto-occipital fascicle, optic radiations, and tapetum fibers [17–19]. In the dominant hemisphere (usually left), all these white matter pathways participate to verbal language and reading; in the minor hemisphere, they participate to attentional functions and visuospatial and social cognition.
2.3
What Does Really Mean Mapping the Vision?
Diffusion tensor imaging (DTI)-based tractography of white matter tracts as well as visual functional MRI can be combined with intraoperative navigation and displayed on neuronavigation. This approach can provide useful information regarding the surgical strategy but is limited in the context of brain tumor as peri-tumoral edema is known to alter the visualization of the white matter tracts on diffusion tractography [20–22]. The OR, as all white matter fascicles, lack consistent anatomical landmark, especially in tumor surgery, where a mass effect and displacement of white matter structures is common. So mapping the vision should be a
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physiological and functional exploration. During awake brain surgery, the anatomical structures physiologically explored are the OR and the visual cortex. Direct electrical stimulation (DES) of OR leads to “positive” and “negative” “phenomena.” The reason for the appearance to a symptom or another is not clearly understood (intensity, site of the DES). The negative symptoms are interpreted as a disturbance of the visual processing, resulting in a scotoma. The positive are interpreted as antero- or retrograde stimulation of neurons resulting in phosphenes in the corresponding contralateral visual field [23, 24]. It has been postulated that the warning of phosphene-evoked stimulation to alert the surgeon of an imminent anatomical disruption of the OR might not be sensitive enough. Indeed, it is possible that phosphenes are triggered only when the stimulation site is already within the OR, thus leading to a visual deficit. However, this limitation might be compensated by increasing the stimulation intensity, thus securing a margin between the resection and the OR (see Fig. 2.2). In fact, complexity of elicited visual phenomena increases in a postero-anterior axis and can be categorized into simple (e.g., flashing lights), intermediate (simple geometrical shapes), and complex forms or visual distortion [25, 26]. It has been described that the left occipital cortex would have a substantially lower sensitivity for stimulation and would lack complex shapes compared with the visually dominant right occipital lobe during extraoperative stimulation a
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Fig. 2.2 (a) Coronal slices of T1 gado in a patient-case with a brain metastasis. Left: at diagnosis. Patient had a complete hemianopia. Middle: Just after puncture of the cyst. Right: 1 month after complete resection under awake conditions with visual field testing according to the quadrants picture naming procedure. Numbers 1 and 2 correspond to tags 1 and 2 of the figure (b). (b) Intraoperative photography. When stimulating tag 2 at 3 mA, the patient was unable to name the picture in the left lower quadrant, as image recognition was disturbed by phosphenes. When stimulating tag 1 at 3 mA, the patient reported phosphenes in the left upper quadrant. The tumor had entered the ventricle in between tag 1 and 2, splitting the upper and lower half of the optic radiations in two separate parts. (c) Postoperative Goldman perimetry 1 month after awake resection, demonstrating a quasi-normal visual field
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using depth electrodes [25]. But in the condition of an awake surgery it should be reminded that the majority of the primary cortex is buried in the calcarine fissure and thus is inaccessible for stimulation. Negative phenomenon might be related to DES of the white matter fascicles connecting the visual cortex to other networks (as inferior longitudinal fasciculus and inferiorfronto-occipital fasciculus), leading to a large variety of symptoms, in the domain of attention (unilateral neglect), reading (alexia), object recognition (visual agnosia), face recognition (prosopagnosia), emotion recognition, empathy, and theory of mind.
2.4
Why to Map the Visual Field?
The VF is a major compound of vision and there is an obvious clinical interest in mapping it. VF defect is a postoperative handicap, which has been largely underestimated by neurosurgeons. While functional disability is minimal with a superior quadrantanopia, permanent hemianopia is a significant handicap that impairs daily life activities, particularly the ability to drive a motor vehicle or to read [27, 28]. The normal monocular human visual field extends to approximately 60° nasally from the vertical meridian in each eye, to 107° temporally, and approximately 70° above and 80 below the horizontal meridian. VF is currently assessed by manual or automated perimeters and it is a time- consuming process (Fig. 2.3). The monocular visual field is measured by perimetry. This may be kinetic, where spots of light are shown on the white interior of a half sphere and slowly moved inward until the observer sees them (Goldman perimeter), or static, where the light spots are flashed at varying intensities at fixed locations in the sphere until detected by the subject. Commonly used perimeters are the automated Humphrey Field Analyzer, the Heidelberg Edge Perimeter, or the Oculus. The binocular VF can be measured by merging results from monocular fields or by using a Binocular Humphrey Esterman VF test (EVFT) (Carl Zeiss Meditec). Binocular visual field testing programs are readily available in various automated perimeters. Concerning the stimulus, five different sizes are defined by Roman numerals I through V. Each stimulus covers a fourfold greater area, ranging from 0.25 mm2 for a size I stimulus to 64 mm2 for a size V stimulus. The light sensitivity threshold is expressed in decibel, calibrated on the most intense perimetric stimulus that the device can display, and not in luminance unit. It is important to know that results between different perimeters are similar, but not identical. That is mainly due to the differences in the hardware used and the luminosity of the devices [29]. As the available luminosity and luminosity steps of one device approaches the other, the results become more comparable, if both perimeters are running the same algorithm. Moreover, visual field testing is a subjective examination. Testing the same eye/patient twice in the same day using the same machine does not produce identical results.
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Fig. 2.3 VF testing: (a) Godman perimeter (b) and monocular VF result, right eye, (c) automated perimeter (d) monocular VF result, right and left eye
For a driving license, most of the European country regulations are based on EU Directive 2009/113/EC that requires a horizontal visual field at least 50° left and right from the vertical meridian in each eye and 120° horizontally in total, and 20° above and below the horizontal meridian (European Commission Official Journal of the European Union 2009/112/EC; Ammend Commission Directive Annex III, 52:223–227. Done at Brussels, 25 August 2009). No description of which visual field test to be used has been included in the European Commission’s regulations. These criteria may vary depending on the country legislation. However, the functional scoring system developed by Esterman is the current gold standard for testing binocular visual fields and is used by many national driving authorities. Mapping of more elaborate aspect of vision as reading, spatial attention, and face and emotion recognition has to be discussed depending on the patient and the lesion location [30].
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When to Map the VF?
As for all brain mapping programming, two elements must be taken into account. The first one is the patient, more specifically his medical history (e.g., ophthalmologic status), his profession, and his hobbies. The visual status of the patient and whether or to what extent a postoperative visual field deficit is acceptable should be a pivotal discussion between the patient and surgeon prior to surgery. The prognosis is important also. Even if a hemianopia is a significant handicap, it has to be balanced with the oncological benefit of a large resection. The situation would be dramatically different for an epilepsy surgery [31–33]. Finally, the localization of the lesion is a major point. This is particularly an issue in anterior temporal lobe resection, which is an efficient treatment for refractory temporal lobe epilepsy [34, 35]. Surgical damage to Meyer loop, the most anterior part of the optic radiation, results in a visual field deficit in between 48 and 100% of patients. Resection of tumors in the posterior temporal lobe or adjacent to the atrium may be also associated with an injury to the OR, resulting in postoperative VF deficits.
2.6
Cortical Visual Evoked Potential
Several reports have suggested that cortical visual evoked potentials (VEPs) can be reliably recorded intraoperatively and that they may predict postoperative visual function. Several reports showed that intraoperative monitoring of the visual cortex is feasible under general anesthesia, using visual evoked potential with subdural electrodes and photic stimulation through closed eyelids with a strobe light [36–38]. The method can be performed during awake craniotomy also. In this situation, direct cortical visual evoked potential (VEP) recording, subcortical recordings from the OR, and subcortical stimulation of the OR can be combined to assess visual function and proximity of the lesion to the OR [39]. Other reports have highlighted the limitations and questioned the reliability of intraoperative VEP monitoring, suggesting that there was no correlation between intraoperative VEP changes and VF outcome [40, 41]. Indeed, the presence of a robust cortical VEP at baseline in visually compromised patients is of concern and brings into question the value of this technique. One possible explanation of this phenomenon is that the VEPs generated by the intact contralateral visual cortex can mask the presumed VEP waveform deficiencies generated by the ipsilateral visual system. Intraoperative electrophysiological monitoring of the visual pathways is feasible under general and local anesthesia. However, it could be postulated that VEP recordings are not reliable for warning the surgeon about an imminent anatomical disruption of the OR.
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eview of the Different Tools and Tasks Designed R to Monitor Visual Field and Other Vision Functions
The different approaches and tools described in this chapter are mainly developed to explore the VF, but new tools targeting the more cognitive aspects of vision are under development and will be shortly discussed. VF evaluation can be done by confrontation, when the examiner, linguist or psychologist, moves his fingers in the four corners of the VF, in a concentric way, as during a classical neurological examination. However, this method lacks accuracy and reproducibility, and is frequently hard to execute in the patient’s and examiner’s position; only rough data can be collected and comparison between successive evaluations is difficult. Specific tools have been then evaluated: dish, screen, and virtual reality headset.
2.7.1 DISH/Large Perimetry Chart Experience In this approach, close to the Goldman test, the patient focused on a target on a large screen or board 3 ft away in the center of his VF. There are few publications, and to date two clinical cases have been reported. Nguyen et al. described for the occipital cortex mapping in one patient, in sitting position, the use of a combined static and kinetic perimetry, with a standard flashing checkerboard task for each eye [42]. The necessity of a sitting position and the cumbersome of the system are real limitations. More recently, Joswing et al. reported an illustrative case of their well-established practice for awake perimetry testing for surgery epilepsy using a visual board [43, 44]. The patient is installed in lateral decubitus position with a large perimetry chart on a stand turned to 90° placed in front of him. The patient is provided with a laser pointer, and, in response to ongoing electrocortical stimulation of several visual cortical areas, has to point exactly toward the perimetry chart to acknowledge any positive or negative changes in his vision. The examiner moved an object toward the target, and the patient signaled when they saw it in their periphery.
2.7.2 Screen Experience Since during awake cortico-subcortical mapping the tasks usually are presented on a laptop or tablet screen, the use of this tool seems obvious. The screen has to be presented at a constant distance, perpendicular to and nearby the patient’s face, that should nevertheless always remain observable (evaluation of facial movements, emotion, possibility of seizures, avoidance of claustrophobia,…).
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Currently, when a standard 15″ screen is used (diagonal 39.6 cm, horizontal 34.5 cm, vertical 19.4 cm), it is placed at 20–25 cm from the nasion, so the horizontal screen length equals the double of the distance screen/eye, offering a lateral angle of 50° (Fig. 2.4).
2.7.2.1 Picture Naming in Quadrants (Montpellier Experience) Another approach has been proposed by Duffau et al.: it consists in presenting two images situated diagonally on a screen divided into four quadrants [45, 46]. This task has been proposed for lesion involving the sagittal stratum in either hemisphere. As language tracts and optic radiations are very close within the temporooccipito-parietal junction, a stimulation of the language pathways would result in naming disturbances for the two diagonally placed pictures, whereas misnaming for only one of the two pictures would be rather linked to a visual disturbance. In the study of Gras-Combe et al., this procedure allowed to avoid full hemianopia in 13 out of the 14 patients, demonstrating its utility. Figure 2.2 provides an illustrative case with full preservation of left VF in a patient with a right temporal metastasis. Optic radiation were mapped intraoperatively by means of picture naming in quadrants.
Fig. 2.4 Scheme of relative distance between eyes and screen, depending on screen’s width, to obtain a lateral angle of 50° × 2
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2.7.2.2 Colored Dots Visual Field Testing (Gent Experience) Since 2012, we have developed at the Saint-Lucas General Hospital Gent a combination of simple visual field testing, preferably with evaluation of extinction (with avoidance of eye movements). When a reference point is placed at the center of the presented screen, and the patient fixes it, only coarse shapes and colors can be recognized out of the central view, so we avoided presenting objects or complex figures, since this induces involuntary eye movements (saccades), biasing the proper visual field evaluation. During VF testing, the patient has to fix a central point (e.g., star, differentiating it from dots), while points appear at the periphery, either in a single quadrant or in opposed quadrants, to allow evaluation of extinction. As background, a black display is preferable (Fig. 2.5a), to enhance the contrast with the presented colors; moreover, most glioma operations are performed in an obscured room (use of microscope, 5 ALA,…), where a bright background can be disturbing. The procedure as used in classical perimetry is subjective: the patient’s answer— to see or not to see the dot (yes or no)—cannot be verified; on the contrary, when the patient mentions a color, the response can be controlled (correct or not): this makes the testing very reliable without loss of time. Another advantage of the use of colors
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Fig. 2.5 Presentation of colored points at peripheral and central locations, uni- or bilateral, and central star to be fixed, on a dark background. (a) Central white star, on black background. (b) All 10 peripheral points. (c) All 10 peripheral + 4 central points. (d) 1 Peripheral point. (e) 2 points, both peripheral. (f) 2 points, 1 peripheral, 1 central
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(except in color-blind people where the test has to be adapted in function of their deficit) is that recognition is very fast, easy for the patient, and even usable in illiterate patients; moreover, it is valuable in tired patients, and easy to verify. Either flashing light points, moving or colored points or combinations can be proposed to the patient. In our opinion, to evaluate correctness of the answer, colored dots are preferable, after exclusion of color blindness. Moreover, description of colors (e.g., “red and blue”) is faster and more reliable than description of the quadrant (e.g., “right inferior and left superior”). Colors are displayed as follows (Fig. 2.5b). Beside the 10 points displayed clockwise at the periphery (10 mm), 4 more points can be presented more centrally in the 4 angles (8 mm), providing some evaluation in case of there is already some degree of visual field deficit (Fig. 2.5c). Either one point can be displayed at one side, or 2 points, one in each hemi-field; in case of 1 testing point, it is preferably located hetero-laterally to the lesion (Fig. 2.5d). To make the test more sensitive, we use 2 points presented in both peripheral hemi-fields (Fig. 2.5e), or 1 peripheral and 1 central (Fig. 2.5f). The occurrence of an extinction phenomenon (the ipsilesional stimulus impedes the perception of the contralesional stimulus) could detect earlier a VF deficit; nevertheless, it should be pointed out that the extinction phenomena is classically described in unilateral neglect meaning that the 2 points test explore vision and attention at the same time, as in ecological conditions. When projected on a Goldman perimetry, the dots are in the normal I3 isoptere, and correspond to a VF retained as standard for quality of life: Superior: 20°, Lateral: 50°, Inferior: 20, Medial: 10° (see Fig. 2.6a, b). The task can be implemented by asking the patient to click on the point on the touch screen; so combined analysis of visual field and movement is obtained. Of course, the color visual field test has to be evaluated and trained preoperatively in regard to classical visual field evaluation with Goldman perimeter. In our approach, the color visual field test is alternated with the G.E.N. Task, which provides global multimodal testing, integrating the visual field evaluation with other-language and non-language-functions. Since the optic radiations are located in the vicinity of inferior fronto-occipital, inferior longitudinal, and arcuate fascicles, these tracts could be lesioned at the same time, and hence evaluated together within one task; this can be obtained with the G.E.N.T. (see Chap. 19), where besides visual field, auditory, reading, naming, nonverbal semantics, and syntax can be evaluated simultaneously by asking the patient to make a short sentence with a written subject or verb and four drawn objects (Fig. 2.7). This task is presented on the same screen at the same distance to the eyes, so immediate and easy switching from one to the other kind of testing is possible without any screen manipulation, avoiding loss of time. However, as for the picture naming in quadrants, there is a risk that the patient makes a saccade as a mean to compensate the stimulation-induced visual field deficit, resulting in a risk of false negative.
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Fig. 2.6 (a) Projection of peripheral colored dots on Goldmann perimeter (monocular). (b) Projection of peripheral colored dots on Esterman Test (binocular)
ESKIMO
Fig. 2.7 One trial of the GENTask. The patient is asked to produce a short sentence like “The Eskimo lives in an igloo”
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2.7.3 Virtual Reality Headset (Angers Experience) VF evaluation with a virtual reality headset (VRH) has been already described, but none to date has yet studied the capabilities offered by these systems in the identification of functional brain areas and implementation of tests of cognitive and visual functions in patients during awake cranial surgery [47–49]. Indeed, the developed headsets and software were oriented for bedside evaluation, and to detect and quantify VF defect in ophthalmologic pathology such as glaucoma. An adapted procedure for VF testing in the condition of an awake surgery needed to be developed. In 2017, we started in Angers to develop this procedure with an Oculus DK1 VRH (Oculus, Menlo Park, California), which has a binocular visual field of 80°. The developed software was based on Esterman test that is officially used to assess visual field defects for driving license authorization according to the European recommendations. In order to be compatible with the VRH, the Esterman test had to be modified. The mean difficulties dealing with VR technology is the rapidity of progress and the constant release of new more performing and affordable VRH. We then adapted our software to the Oculus DK2 which has a binocular visual field of 90°. Our modified Esterman test in its latest version explored the 45° around the central visual axis of a binocular visual field, which does not meet all the French criteria on driving licenses, but can detect important visual defects that may impair the quality of life. In the operative room, while the neurosurgeon performs direct cortical or subcortical electrostimulation, the orthoptist provides luminous stimuli on the control screen. The patient gives an oral answer to the examiner according to whether or not he sees the luminous stimulus (Fig. 2.8). Our goal was to assess the efficiency of the VRH in detecting visual defects, rather than comparing two bedsides visual field assessment techniques. Nevertheless, we compared our test with an automated perimetry and comparison showed that 90% of the patients with a VF defect were well classified with our approach. The proof of concept of this approach was done for a 66-year-old male, right- handed, blind in his right eye due to a history of ischemic optic neuropathy, who had surgery for a left parieto-temporal malignant glioma [50]. We then adapted our software to another VRH model: the Samsung Gear VR combined with a Samsung S7 smartphone (visual field 96°). Presently, we are using the HTC Vive (visual field 110°) [51]. The major advance was to combine the VRH HTC Vive with an eye-tracking device (Tobii Pro SDK) able to track the full HTC Vive field of view and to perform a pupil measurement. The first VF test was piloted by an orthoptist, enhancing accuracy, but weighting down the procedure. We developed another version, easier to pilot, exploring a VF of 80° with six possible red dots on a black background (Fig. 2.9). Indeed, the maximum visual field attainable in the virtual reality headset, taking into account its mechanical characteristics, is 110°. However, if we keep the foam to maximize the user comfort and if we do not impose to press the headset against the face as much as possible, then the visual field is around 90°.
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Fig. 2.8 Modified Esterman test. (a) View of the screen piloted by the orthoptist. Left: the gray area represents what the patient is seeing. Each stimulus appears as a white dot on a gray background, while the patient has to stare the central yellow dot; Right: modified Esterman test grid, allowing the orthoptist to select the part of the visual field to be tested and one of the 20 pre-settled points; (b) patient wearing the virtual reality headset
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Fig. 2.9 VF testing with the VRH HTC vive. (a) What the patient sees, the eight possible dots are presented, (b) the same dots projected on an Esterman grid; (c) perioperative view, with exploration of social vision using interactive avatars. The screen shows what the patient is seeing in the VRH, his gaze is represented as a green spot
According to our experience, the phosphenes elicited by DES are more distinct in patients wearing a VRH with a dark background. What the patient sees in the VRH is projected on one of the neuronavigation system’s screen. Thanks to the eye tracking, the patient gaze can be followed online on the screen, materialized as a
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green point (Fig. 2.9). This gives an essential control of the patient gaze, and warrants that the patient was really fixing the central dot during the VF testing, without eye saccades. Moreover, once the task has been completed, gaze layout can be displayed on the screen as lines, heat map, or statistics, combined if necessary with pupillometry data, which is particularly helpful during testing of a complex aspect of vision (Fig. 2.10). Now, a prospective study is ongoing comparing with all the described limitations, our VF test to an automatized perimetry (TRIAL.GOV NCT04288505). In the future, technical features of Virtual Reality Headset are going to be improved, and it will probably soon be possible to explore a wider visual field in these devices. Parallelly, we are exploring more cognitive aspects of the vision, such as attention and visuospatial and social cognition. Indeed, there are several interactions between awareness, spatial attention, and vision of affectively and socially significant items or faces [52, 53]. VR offers tools for creating realistic simulations of social situation. Eye-tracking sensor technology can determine the patient’s level of attention, to where and to
Fig. 2.10 The eye-tracking recording (blue line) after a social vision task. The patient is asked to search for the avatar trying to make visual contact. Once the avatar looking at the patient is identified and visual contact is established for a period of 0.6 s, the avatar expresses a dynamic facial emotion. The patient is asked to describe the avatar’s emotion or to describe his feelings about the desire to communicate or engage in social contact expressed by the avatar
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what the patient is focusing his attention, as well as his pupillometry. Interactivity is another interesting aspect of VR. Eye-tracking technology provides a whole new way to interact with VR content. For example, eye-tracking data of participants can be used for real-time control of a virtual character’s attention or facial emotion (Figs. 2.9 and 2.10). We demonstrated the safety of this approach with VRH during a brain mapping procedure [54]. We are now developing VR interactive tasks, using avatars and more recently actors, allowing to explore with a VRH combined with eye tracking, during a brain mapping procedure, the VF, the attentional processes, and theory of mind (Fig. 2.10) [55].
2.8
Conclusion
Different approaches have been developed to explore the VF during an awake surgery, and many groups use them already in routine. However, the value of intraoperative mapping of the visual pathways during resection of tumors adjacent to the OR is still unclear. That could be explained by several points. First, to test the reliability of all these perioperative VF testing, they would have to be compared with bedside binocular automated perimetry. Nevertheless, as mentioned above, the results between different perimeters are not identical and VF testing is a subjective examination. The variability is significant, and that makes the comparison between a perioperative perimetry test and an automated perimetry quite difficult. Secondly, a larger number of comparable patients and a randomized trial are needed to establish the benefit of VF mapping in terms of eligibility to drive, or more globally on quality of life. The VF is an important compound of the vision, but does not represent itself the whole complex cognitive process of the vision. Vision and language are intimately processed in the dominant hemisphere. On the other hand, attention, visuospatial cognition, and social vision are interconnected also in the “minor hemisphere” (see Chaps. 4 and 18). Attentional or visual cognition defects can be more disabling than a VF defect, leading to the necessity to develop more comprehensive approaches to map the “vision,” and to test the patients before and after the surgery.
References 1. Vernon D. Visual cognition. In: Ikeuchi K, editor. Computer vision: a reference guide. Boston: Springer US; 2014. p. 860–2. 2. Adolphs R. Recognizing emotion from facial expressions: psychological and neurological mechanisms. Behav Cogn Neurosci Rev. 2002;1:21–62. 3. Carreiras M, Armstrong BC, Perea M, Frost R. The what, when, where, and how of visual word recognition. Trends Cogn Sci. 2014;18:90–8. 4. Freiwald WA. The neural mechanisms of face processing: cells, areas, networks, and models. Curr Opin Neurobiol. 2020;60:184–91.
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5. Riesenhuber M, Poggio T. Neural mechanisms of object recognition. Curr Opin Neurobiol. 2002;12:162–8. 6. Harris LR, Jenkin M. Vision and attention. In: Jenkin M, Harris L, editors. Vision and attention. New York: Springer; 2001. p. 1–17. 7. Prasad S, Galetta SL. Anatomy and physiology of the afferent visual system. Handb Clin Neurol. 2011;102:3–19. 8. Hansen T, Pracejus L, Gegenfurtner KR. Color perception in the intermediate periphery of the visual field. J Vis. 2009;9:26.1–12. 9. Fademrecht L, Bülthoff I, de la Rosa S. Action recognition in the visual periphery. J Vis. 2016;16:33. 10. Rosenholtz R. Capabilities and limitations of peripheral vision. Annu Rev Vis Sci. 2016;2:437–57. 11. Huff T, Mahabadi N, Tadi P. Neuroanatomy, visual cortex. In: StatPearls. Treasure Island: StatPearls Publishing; 2020. 12. Mishkin M, Ungerleider LG. Contribution of striate inputs to the visuospatial functions of parieto-preoccipital cortex in monkeys. Behav Brain Res. 1982;6:57–77. 13. Di Carlo DT, Benedetto N, Duffau H, Cagnazzo F, Weiss A, Castagna M, Cosottini M, Perrini P. Microsurgical anatomy of the sagittal stratum. Acta Neurochir (Wien). 2019;161:2319–27. 14. Jitsuishi T, Hirono S, Yamamoto T, Kitajo K, Iwadate Y, Yamaguchi A. White matter dissection and structural connectivity of the human vertical occipital fasciculus to link vision-associated brain cortex. Sci Rep. 2020;10:820. 15. Rokem A, Takemura H, Bock AS, Scherf KS, Behrmann M, Wandell BA, Fine I, Bridge H, Pestilli F. The visual white matter: the application of diffusion MRI and fiber tractography to vision science. J Vis. 2017;17:4. 16. Takemura H, Pestilli F, Weiner KS, Keliris GA, Landi SM, Sliwa J, Ye FQ, Barnett MA, Leopold DA, Freiwald WA, et al. Occipital white matter tracts in human and macaque. Cereb Cortex. 2017;27:3346–59. 17. Capilla-Guasch P, Quilis-Quesada V, Regin-Neto M, Holanda VM, González-Darder JM, de Oliveira E. White matter relationships examined by transillumination technique using a lateral transcortical parietal approach to the atrium: three-dimensional images and surgical considerations. World Neurosurg. 2019;132:e783–94. 18. Koutsarnakis C, Kalyvas AV, Komaitis S, Liakos F, Skandalakis GP, Anagnostopoulos C, Stranjalis G. Defining the relationship of the optic radiation to the roof and floor of the ventricular atrium: a focused microanatomical study. J Neurosurg. 2019;130:1728–39. 19. Peltier J, Nicot B, Baroncini M, Zunon-Kipré Y, Haidara A, Havet E, Foulon P, Page C, Lejeune J-P, Le Gars D. Anatomie de la substance blanche périventriculaire. Neurochirurgie. 2011;57:151–5. 20. Roux FE, Ibarrola D, Lotterie JA, Chollet F, Berry I. Perimetric visual field and functional MRI correlation: implications for image-guided surgery in occipital brain tumours. J Neurol Neurosurg Psychiatry. 2001;71:505–14. 21. Shinoura N, Suzuki Y, Yamada R, Tabei Y, Saito K, Yagi K. Relationships between brain tumor and optic tract or calcarine fissure are involved in visual field deficits after surgery for brain tumor. Acta Neurochir (Wien). 2010;152:637–42. 22. Winston GP, Daga P, White MJ, Micallef C, Miserocchi A, Mancini L, Modat M, Stretton J, Sidhu MK, Symms MR, et al. Preventing visual field deficits from neurosurgery. Neurology. 2014;83:604–11. 23. Dobelle WH, Mladejovsky MG. Phosphenes produced by electrical stimulation of human occipital cortex, and their application to the development of a prosthesis for the blind. J Physiol. 1974;243:553–76. 24. Šteňo A, Hollý V, Fabian M, Kuniak M, Timárová G, Šteňo J. Direct electrical stimulation of the optic radiation in patients with covered eyes. Neurosurg Rev. 2014;37:527–33. 25. Jonas J, Frismand S, Vignal J-P, Colnat-Coulbois S, Koessler L, Vespignani H, Rossion B, Maillard L. Right hemispheric dominance of visual phenomena evoked by intracerebral
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s timulation of the human visual cortex: Right Hemispheric Dominance of Visual Phenomena. Hum Brain Mapp. 2014;35:3360–71. 26. Lee HW, Hong SB, Seo DW, Tae WS, Hong SC. Mapping of functional organization in human visual cortex: electrical cortical stimulation. Neurology. 2000;54:849–54. 27. Bowers AR. Driving with homonymous visual field loss: a review of the literature. Clin Exp Optom. 2016;99:402–18. 28. Zihl J. Visual scanning behavior in patients with homonymous hemianopia. Neuropsychologia. 1995;33:287–303. 29. Manji H, Plant GT. Epilepsy surgery, visual fields, and driving: a study of the visual field criteria for driving in patients after temporal lobe epilepsy surgery with a comparison of Goldmann and Esterman perimetry. J Neurol Neurosurg Psychiatry. 2000;68:80–2. 30. Chan-Seng E, Moritz-Gasser S, Duffau H. Awake mapping for low-grade gliomas involving the left sagittal stratum: anatomofunctional and surgical considerations. J Neurosurg. 2014;120:1069–77. 31. Blume WT, Whiting SE, Girvin JP. Epilepsy surgery in the posterior cortex. Ann Neurol. 1991;29:638–45. 32. Salanova V, Andermann F, Olivier A, Rasmussen T, Quesney LF. Occipital lobe epilepsy: electroclinical manifestations, electrocorticography, cortical stimulation and outcome in 42 patients treated between 1930 and 1991. Surgery of occipital lobe epilepsy. Brain J Neurol. 1992;115(Pt 6):1655–80. 33. Yang P-F, Jia Y-Z, Lin Q, Mei Z, Chen Z-Q, Zheng Z-Y, Zhang H-J, Pei J-S, Tian J, Zhong Z-H. Intractable occipital lobe epilepsy: clinical characteristics, surgical treatment, and a systematic review of the literature. Acta Neurochir (Wien). 2015;157:63–75. 34. Ebeling U, Reulen HJ. Neurosurgical topography of the optic radiation in the temporal lobe. Acta Neurochir (Wien). 1988;92:29–36. 35. Sincoff EH, Tan Y, Abdulrauf SI. White matter fiber dissection of the optic radiations of the temporal lobe and implications for surgical approaches to the temporal horn. J Neurosurg. 2004;101:739–46. 36. Curatolo JM, Macdonell RA, Berkovic SF, Fabinyi GC. Intraoperative monitoring to preserve central visual fields during occipital corticectomy for epilepsy. J Clin Neurosci. 2000;7:234–7. 37. Kamada K, Todo T, Morita A, Masutani Y, Aoki S, Ino K, Kawai K, Kirino T. Functional monitoring for visual pathway using real-time visual evoked potentials and optic-radiation tractography. Neurosurgery. 2005;57:121–7; discussion 121–7. 38. Ota T, Kawai K, Kamada K, Kin T, Saito N. Intraoperative monitoring of cortically recorded visual response for posterior visual pathway. J Neurosurg. 2010;112:285–94. 39. Shahar T, Korn A, Barkay G, Biron T, Hadanny A, Gazit T, Nossek E, Ekstein M, Kesler A, Ram Z. Elaborate mapping of the posterior visual pathway in awake craniotomy. J Neurosurg. 2018;128:1503–11. 40. Cedzich C, Schramm J, Fahlbusch R. Are flash-evoked visual potentials useful for intraoperative monitoring of visual pathway function? Neurosurgery. 1987;21:709–15. 41. Raudzens PA. Intraoperative monitoring of evoked potentials. Ann N Y Acad Sci. 1982;388:308–26. 42. Nguyen HS, Sundaram SV, Mosier KM, Cohen-Gadol AA. A method to map the visual cortex during an awake craniotomy. J Neurosurg. 2011;114:922–6. 43. Girvin JP. Operative techniques in epilepsy. Cham: Springer International Publishing; 2015. 44. Joswig H, Girvin JP, Blume WT, Burneo JG, Steven DA. Awake perimetry testing for occipital epilepsy surgery. J Neurosurg. 2018;129:1195–9. 45. Duffau H, Velut S, Mitchell M-C, Gatignol P, Capelle L. Intra-operative mapping of the subcortical visual pathways using direct electrical stimulations. Acta Neurochir (Wien). 2004;146:265–9; discussion 269–70. 46. Gras-Combe G, Moritz-Gasser S, Herbet G, Duffau H. Intraoperative subcortical electrical mapping of optic radiations in awake surgery for glioma involving visual pathways. J Neurosurg. 2012;117:466–73.
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47. Kimura T, Matsumoto C, Nomoto H. Comparison of head-mounted perimeter (imo®) and Humphrey Field Analyzer. Clin Ophthalmol Auckl N Z. 2019;13:501–13. 48. Tsapakis S, Papaconstantinou D, Diagourtas A, Droutsas K, Andreanos K, Moschos MM, Brouzas D. Visual field examination method using virtual reality glasses compared with the Humphrey perimeter. Clin Ophthalmol Auckl N Z. 2017;11:1431–43. 49. Wroblewski D, Francis BA, Sadun A, Vakili G, Chopra V. Testing of visual field with virtual reality goggles in manual and visual grasp modes. Biomed Res Int. 2014;2014:206082. 50. Mazerand E, Le Renard M, Hue S, Lemée J-M, Klinger E, Menei P. Intraoperative subcortical electrical mapping of the optic tract in awake surgery using a virtual reality headset. World Neurosurg. 2017;97:424–30. 51. Casanova M, Clavreul A, Soulard G, Delion M, Aubin G, Ter Minassian A, Seguier R, Menei P. Immersive virtual reality and ocular tracking for brain mapping during awake surgery: prospective evaluation study. J Med Internet Res. 2021;23(3):e24373. 52. Bernard F, Lemée J-M, Ter Minassian A, Menei P. Right hemisphere cognitive functions: from clinical and anatomic bases to brain mapping during awake craniotomy part I: clinical and functional anatomy. World Neurosurg. 2018a;118:348–59. 53. Lemée J-M, Bernard F, Ter Minassian A, Menei P. Right hemisphere cognitive functions: from clinical and anatomical bases to brain mapping during awake craniotomy. Part II: neuropsychological tasks and brain mapping. World Neurosurg. 2018;118:360–7. 54. Delion M, Klinger E, Bernard F, Aubin G, Minassian AT, Menei P. Immersing patients in a virtual reality environment for brain mapping during awake surgery: safety study. World Neurosurg. 2020;134:e937–43. 55. Bernard F, Lemée J-M, Aubin G, Ter Minassian A, Menei P. Using a virtual reality social network during awake craniotomy to map social cognition: prospective trial. J Med Internet Res. 2018b;20:e10332.
3
Frontal Eye Fields Guillaume Herbet
3.1
Anatomy and Connectivity of FEFs
3.1.1 Physiological Definition and Brief Historical Background The frontal eye field is defined physiologically as a restrict area of the primate’s posterior prefrontal cortex whose low-intensity electrostimulation is associated with involuntary ocular movements [1, 2]. Such observation go back far into the past; indeed, David Ferrier [3] was the first to report that, in some animals (including monkeys), stimulating an area situated in the posterior half of the superior and middle frontal cortex caused head and eye movements to the opposite side as well as dilatation of pupils in some cases. Since that time, the finding of a frontal ocular area has been widely replicated, first in lower and higher primates (e.g., [4, 5]) and then in humans in the context of neurosurgery. On the latter point, Foerster [6, 7] found conjugate horizontal deviation of the eyes to the opposite side, and sometimes upward deviation, in response to stimulation of the posteriormost portion of the middle frontal gyrus. Likewise, Penfield and collaborators [8, 9] not only confirmed that applying stimulation on the posterior part of the dorsolateral prefrontal cortex (caudal part of the mid-lateral area according to the authors) caused “adversive movements” of the eyes toward and upward the hemisphere contralateral to the stimulation, but also reported that epileptic discharges in areas situated in or in the vicinity of the ocular frontal areas replicated some of the clinical observations evoked during stimulation, including eye movements [10]. Penfield and associates also identified eye-related areas in other frontal structures, including the precentral gyrus [9].
G. Herbet (*) Department of Neurosurgery, Gui de Chauliac Hospital, Montpellier & Institute of Functional Genomics, University of Montpellier, INSERM, CNRS, Montpellier, France e-mail: [email protected] © Springer Nature Switzerland AG 2021 E. Mandonnet, G. Herbet (eds.), Intraoperative Mapping of Cognitive Networks, https://doi.org/10.1007/978-3-030-75071-8_3
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3.1.2 Localization of the FEFs As reviewed by Vernet et al. [11], the precise location of the FEF is variable across species (i.e., nonhuman primates versus humans) and depends on both the technique used to locate it (i.e., electrostimulation, PET, fMRI, TMS) and the behavior paradigm employed to trigger its neural activity. In the unanesthetized monkey, the FEF has been typically found in the anterior bank of the pre-arcuate sulcus around the posterior end of the sulcus principalis, using either electrostimulation procedure (e.g., [12–14]) or electrophysiological recordings in concert with oculomotor behavior tasks (e.g., [15, 16]). In humans, the exact location of the FEF slightly diverges across studies. Neuromodulation studies in patients implanted with subdural electrodes for epilepsy surgery identified the FEF “in front of or at the level of the motor representation [of the hand]” [17], or “at the posterior end of the middle frontal gyrus immediately anterior to the precentral gyrus and in proximity to the superior frontal sulcus” [18]. Electrostimulation studies conducted with “awake” patients in the context of low-grade glioma surgery confirmed the FEF as located in the posteriormost part of the middle frontal gyrus in front of the primary motor cortex, just below the intersection of the precentral sulcus and the superior frontal sulcus [19, 20]. It is worthing of note, however, that electrostimulation procedure has potential shortcomings in its ability to identify the FEF as it cannot interfere with the neurons situated in the adjacent sulci at low-intensity threshold, explaining why neuroimaging studies provide different results (see below). Moreover, the functional definition of the FEFs is intrinsically linked to observation of ocular movements in response to stimulation, though other visuo-motor activities are able to activate the FEFs. However, because neurosurgery is a clinical situation and not an experimental one, such visuo-motor tasks are routinely not included in the intraoperative protocol to spot the FEF. As briefly mentioned above, neuroimaging literature mainly based on positron emission tomography (PET) and functional magnetic resonance imaging (fMRI) has provided a more complete picture of the possible location of the FEFs, with the advantage of using a wide range of behavior tasks able to fire it, including without being exhaustive self-paced, externally paced, imagined, visually guided, and memory-guided saccades (for a detailed review, see [11, 21, 22]). In a meta-analysis of available PET datasets, Paus [22] found a consistent location of the FEF very close to the precentral sulcus with however a great deal of across-study variability along a medial-to-lateral axis possibly due to the type of visuo-motor tasks employed. In the review of Amiez and Petrides [12] based on fMRI literature, the FEF was reportedly located in the depth of the precentral gyrus at the intersection with the superior frontal sulcus. However, in individual studies, the FEF was occasionally found in the anteriormost part of precentral gyrus [23], or at least extending in this region [24]. Other fMRI works have suggested an inferior to superior functional subdivision of the FEF [25–27], possibly corresponding to reflexive and volitional demands, respectively [21]. In brief, neuroimaging literature mainly localizes the FEF in the precentral sulcus close to the superior frontal sulcus with however some variabilities that may reflect either task requirements or differences in the
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statistical approach used to process neuroimaging data. Alternatively, the across- study variability in the precise localization of the FEF may be explained by the considerable interindividual variability in sulcal anatomy notably regarding its shape, size, and location [28].
3.1.3 Connectivity of FEFs The frontal eye fields are at the heart of a complex and very distributed sensorimotor network supporting the planning, execution, and regulation of saccadic eye movements. This neural circuitry has been the target of numerous reviews; the aim here is to provide a general overview of what it is currently known without going into too much details. Besides, we have to keep in mind that much of it is accepted about the anatomical connectivity of the FEFs is derived from either autoradiographic or electrophysiological recording techniques performed in nonhuman primates. Generally, experimental evidence suggests that the FEFs exert a directed influence on the oculomotor system through four main subcortical, descending pathways [29], all of which have been reviewed by Squire et al. [30] as follows (Fig. 3.1). The first that projects to the deep layer of the ipsilateral colliculus has a direct influence on all aspects of saccade-related activity [31]. The second projects to the ipsilateral basal ganglia with a relay in the striatum. The third projects to the cerebellum via the pontine nuclei. The fourth projects to mesencephalic and pontine nuclei that form what is called the saccade generator circuit. Besides, the FEFs are closely connected
Fig. 3.1 The connectivity and anatomical locations of the frontal eye field (FEF) and other structures within the visual and oculomotor systems of the rhesus macaque monkey brain. Left panel, diagram of the connectivity of the FEF (orange) with other visual and oculomotor structures. Some connections that do not directly involve the FEF are omitted. Right panel, locations of the brain regions pictured in the left panel shown in the lateral view of the monkey brain. In both panels, surface structures other than the FEF are colored darker blue. Deep structures are illustrated as lighter blue and with a dashed outline. Abbreviations: BG basal ganglia, BSG brainstem saccade generator, Cbl cerebellum, Ex Vis Ctx extrastriate visual cortex, LIP lateral intraparietal area, SC superior colliculus, SEF supplementary eye field, Thal thalamus, V1 primary visual cortex. From Ryan Fox Squire et al. [30] Frontal eye field. Scholarpedia, 7(10):5341, revision #13743. This figure is licensed under the Creative Commons Attribution 3.0: http://www.scholarpedia.org/article/Frontal_eye_field
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to a number of fronto-cortical regions also involved in saccadic eye movements, an anatomo-functional organization which seems to be well preserved between monkeys and humans [12]. This includes the supplementary eye field and the cingulate eye field. In humans, the former is located in the superior frontal gyrus, rostral to the supplementary motor area, whereas the latter lodges within the cingulate sulcus [12, 29]. The FEFs have also bi-directional connections with different areas of the visual system in both the ventral (inferior-temporal cortex) and the dorsal (postero-parietal) stream, as revealed by tracer studies in monkey [32–34]. A recent resting-state functional connectivity study, performed in monkey and humans concurrently, not only confirmed the results from autoradiographic studies, but also indicated that the functional connectivity of the FEF is globally preserved across the two species. More specifically, the FEF was coupled in humans with multiple frontal areas (including the supplementary eye field, the cingulate eye field, the dorsolateral prefrontal cortex, and an area around the inferior frontal sulcus), posterior parietal areas (especially the inferior parietal lobule, the intraparietal sulcus and the precuneal cortex), and temporo-occipital areas (especially within and around the lateral occipitotemporal sulcus) [35]. Taken as a whole, current literature demonstrates that the FEF is intimately connected, functionally and structurally, with both the oculomotor and the visual systems.
3.2
Putative Functions of the FEF
3.2.1 Ocular-Motor Behaviors As evoked above, it is widely accepted that the FEF is strongly involved in the network supporting planning, generation, and control of saccades as it interfaces with a wide range of cortical or subcortical areas known to participate in such ocular-motor activities. The results from fMRI studies indeed showed that numerous behavior tasks, manipulating the reflexive, voluntary, or predictive aspect of saccadic activity, are able to trigger functional activity of the FEFs (for a review, [11]). However, fMRI is not designed to draw causal anatomo-functional interferences. Therefore, patients’ performances are of major interest to better define the functional involvement of a given area. Lesion studies, mainly dealing with stroke patients, reportedly described oculomotor deficits following partial or major insult to the FEF. Lesions affect either the reflexive or the voluntary aspect of saccadic movements, with however a greater impact on intentional saccades [11]. These disturbances generally manifest by increased latencies in the ipsi- or/and contralesional visual fields, irrespective to the behavior paradigms used. In a study using a comprehensive assessment of oculomotor behaviors, it was shown that the FEF has an important role in the disengagement from central fixation, the control of contralateral saccades, saccade prediction and the control of smooth pursuit and
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optokinetic nystagmus in the ipsilesional hemisphere [36]. Another example is that FEF damage can induce difficulties in performing vertical saccades during visual exploration [37]. Today, most of what has been found in patients has been replicated using another technique allowing causal anatomo-functional correlations in neurologically healthy participants, namely transcranial magnetic stimulation (TMS). These studies, reviewed by Vernet et al. [11], generally showed that TMS impulses induce longer latencies mainly of contralesional or bilateral saccades in the context of reflexive or voluntary saccades. They also indicated that TMS can interfere with saccade execution in anti-saccade or memory-guided behavioral paradigms.
3.2.2 Saliency Map and Saccade Target Selection Rapid saccadic eye movement is needed to orient gaze toward items of interest in an often complex and fast-changing visual environment. Currently, it is believed that the FEF may participate in generating a salience map that gauges and selects the most salient or conspicuous aspects of the visual scene for further foveal processing. This process of “saccade target selection” is guided by both bottom-up, perceptual aspect of visual items and top-down knowledge (i.e., goals or expectations) of the individual [38]. As a matter of fact, pharmaceutical inactivation of the FEF in monkeys can lead to a target-selection deficit [39], as for the superior colliculus [40]. In a visual search paradigm, this deficit manifests by a greater proportion or erroneous saccades toward visual distractors while the capacity of performing saccades toward visual targets is preserved in the absence of such distractors.
3.2.3 Visuospatial Attention and Awareness By virtue of its connections in visual associative areas [34], the FEF is increasingly thought as a visual area itself, at the interface between the oculomotor system and the network maintaining aspects of visuospatial attention. In this regard, it is interesting to highlight that, in the monkey brain, fMRI studies have suggested a functional compartmentalization of the FEF into a lateral and medial sector that might be involved in, respectively, short and ample saccades [41]. Consistent with the supposed behavior role of short and ample saccades during the vision of natural or dynamics environments (i.e., short saccades allow precise identification of object features in the service of grasping and manipulation whereas larger saccades are associated with reaching and trunk movements), it was shown that ventral FEF was functionally coupled with areas of the ventral stream involved in object processing and manipulation while dorsal FEF synchronized with areas of the dorsal stream. This shows how involved is the FEF, though differentially, in visually guided
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behaviors—at least in monkeys. This functional division of the FEF seems to agree with tracer studies showing that the ventral and the dorsal FEF have a dissimilar pattern of anatomical connectivity. For example, the work by Schall et al. [34] in monkeys indicated that the ventral FEF (equivalent to lateral) hosts projections from the foveal representation in retinotopically organized areas and from areas that represent the central vision in the inferotemporal cortex whereas the medial FEF (equivalent to dorsal) received projections from the peripheral representation in retinotopically organized areas and from areas involved in peripheral vision. This connectivity, both functional and structural, in the visual system has led to the hypothesis whereby the FEF might be cognitively penetrated and thus might play a role in the control of visual attention, independently of its role in saccadic movements. This hypothesis has been at least partially validated in lesional studies performed in the monkey, as unilateral lesions of the FEF did cause inattention to stimuli on the opposite side of the visual field in various studies (e.g., [42–44]). This observation agrees with studies showing that pharmaceutical inactivation of FEF causes an increase of reaction times to detect contralateral targets in visual search paradigms in the absence of saccades, suggesting that FEF does contribute to attention shifts and perception (e.g., [45]). This role has been further supported by observation that low-intensity stimulation of the FEF, adjusted for hindering the overt production of saccadic movements, can transitorily improve the deployment of covert attention [46]. In humans, the FEF has currently a central position in the most authoritative anatomo-functional models of attention. For example, in the model by Corbetta and Shulman [47] mainly based on fMRI and lesional literature, the FEF together with the intraparietal sulcus—forming the so-called dorsal attention system—is critical for controlling the top-down aspect of attention, while the ventral system composed of the temporoparietal junction and the inferior frontal gyrus is rather involved in detecting and shifting attention toward unexpected stimuli. Interestingly enough, the FEF especially in the right hemisphere is thought to be an area allowing functional exchanges between the two attention systems [48] as it is also modulated by stimuli-driven reorienting of attention [49]. The possible coupling between attention and saccades was evidenced in a quantitative meta-analysis of fMRI datasets where functional maps of, respectively, attention shifts and saccadic eye movements widely overlapped, notably in the FEF [50]. Neuropsychological studies in humans confirmed the role of the FEF, especially in the right hemisphere, in visuospatial attention, as its damage is associated with spatial neglect. For example, Thiebaut de Schotten et al. [51] assessed the cortical and white matter correlates of spatial neglect based on the behavioral performances of stroke patients. Among the range of analyses performed, an overlay subtraction analysis was achieved between patients with neglect versus patients without neglect. The results revealed that patients with neglect were more frequently lesioned in the frontoparietal network, including but not uniquely the right FEF. On a different but interconnected matter, fMRI and TMS studies have suggested a role of the left FEF in the modulation of conscious visual perception possibly through the system of attention reorienting [52, 53].
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I ntraoperative Mapping of the FEF in “Awake” Surgery for Diffuse Low-Grade Glioma
To the best of our knowledge, there are only two studies describing the clinical manifestations associated with electrostimulation of the FEF in the context of glioma surgery. In the first one, direct electrostimulation along with electro-oculography recordings was performed in a 34-year woman operated on for a glioma invading the right frontal cortex including the FEF [19]. Before the surgical procedure, a functional MRI was achieved in an attempt to identify the network of areas involved in saccadic movements, in particular the FEF. A simple oculomotor task that consisted in performing self-paced symmetric horizontal saccades was used as functional localizer. As expected, the task triggered functional activations in the supplementary eye field, in the intraparietal sulcus, and in the left FEF (located in the precentral gyrus, at the intersection with the superior frontal sulcus according the figure provided). The lack of significant activation in the ipsilesional FEF was interpreted as due to the lesional infiltration of the structure even if an activation was revealed when using less conservative statistical threshold. In the operating theater, electrostimulation was applied on the cerebral cortex while the patient was engaged in two concurrent behavioral scenarios. In the first condition, the patient was simply asked to visually fix on a target placed in front of her eyes. In the alternative condition (a saccade task similar to that used in MRI scanner), the patient was asked to perform continuously horizontal saccades. In the first condition, four sites located in the most anterior part of the precentral gyrus, behind the lateral half of the middle frontal gyrus, caused conjugate contraversive eye movements when stimulated at low current intensity (1.8 mA in average). Ocular metrics suggested not saccadic, but smooth pursuit ocular deviations. In the second one, suppression of saccades was provoked four times at one site (a site identical to condition one) (Fig. 3.2). In the second study, six glioma patients in whom ocular deviations were evoked in the frontal cortex were included [20] (Fig. 3.3). Importantly, sites associated with ocular deviations could be situated in the frontal white matter as well. At the cortical level, ocular deviations were evoked by interfering with an area located in front of the primary motor cortex of the face within the posterior part of the middle frontal gyrus, just below the intersection of the precentral gyrus and the superior frontal sulcus. This anatomical situation corresponds to what is generally observed in electrostimulation studies conducted with tumor [19] or epileptic patients [18, 54]. Interestingly, while the majority of sites were associated with horizontal ocular deviations, a conjugate upward deviation was elicited in one patient (in addition to a horizontal one), an observation that has been already reported, albeit rarely, in the previous medical literature (e.g., [7, 8, 55]). As hypothesized by Kaiboriboon et al. [56], this kind of results suggest that the FEF might be topologically severed into two subareas along a rostral-to-caudal axis. At the subcortical level, three sites associated with horizontal deviations were identified in the white matter underneath the cortical FEF, in particular in fibers running under the posterior half of the middle frontal gyrus. Vertical deviations were not induced possibly because the fibers emanating from the caudal FEF were not stimulated. As diffusion tractography was not
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Fig. 3.2 Location of the FEF in a study combining preoperative activation fMRI and direct electrostimulation in a single glioma patient. (a) Preoperative fMRI showing left FEF, supplementary eye field, and parietal activation, induced by a self-paced horizontal saccade task. R right, L left. (b) Intraoperative picture overlaid onto the three-dimensional reconstruction of the patient’s brain. Electrostimulation of the regions labeled 20, 21, 22, and 24 elicited contraversive smooth eye movements whereas the area corresponding to the label 21 elicited both smooth eye movements and saccade suppression. Bar represents 1 cm in length (with permissions from WOLTERS KLUWER HEALTH, INC)
used in this study and because a vast number of association and projection tracts run in the white matter deep in the middle frontal gyrus, it was not possible to identify which fibers formed the oculomotor tract. However, in view of the fronto-striatal tract’s projections in both the FEF and the striatum (a nucleus known to participate in oculomotor behaviors, see above) [57], it is likely that the oculomotor tract might in fact be part of this projection tract. All-in-all, although brain stimulation studies conducted with glioma patients are at the very least rare, they not only confirmed the location of the FEF in the posteriormost part of the middle frontal gyrus, around the junction between the precentral and the superior frontal sulci, but also identified for the first time the white matter connections that might be involved in eye control.
3.4
Functional Consequences of FEF Surgical Removal
To our knowledge, there are currently no reports assessing the functional consequences of surgical removal of the FEF in the particular context of glioma neurosurgery.1 However, as the anatomo-functional organization of the FEF seems 1 Note that Bourdillon et al. [56] reported the case of an 11-year old woman in whom a surgical resection of the right FEF was performed due to the presence of a cavernoma that caused epileptic discharge (during seizure, the patient experienced tonic eye deviation toward the opposite side). According the authors, no neurological impairments were observed after surgery but we do not know the way the patient was assessed.
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Fig. 3.3 Cortical and subcortical topography of sites associated with oculomotor deviations as revealed by electrostimulation mapping in diffuse low-grade patients (with permissions from Springer)
phylogenetically well preserved between humans and monkeys [12], the results from ablation studies conducted with the latter are in our opinion particularly relevant—even if, of course, the pathophysiological bases of the resulting deficits are not exactly the same (i.e., acute lesion in monkey versus graded lesion in humans).
3.4.1 On Ocular Behaviors Historically, Ferrier and Yeo [59] were the first to perform ablations of the FEF in macaque and dog-faced monkeys. They observed that unilateral lesioning of this
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structure caused a deviation of both the head and the eyes toward the ipsilesional side. However, contrary to bilateral lesions for which the impairment was permanent, the deviations dissipated in the next days. Soon after, Sherrington [60] found that the removal of the cerebral region anterior to the motor cortex provoked conjugate horizontal of the eyes on the opposite side. Since that time, the effect of ablating the FEF on ocular behaviors has been repeatedly reported. For example, Schiller [61] demonstrated that both unilateral and bilateral FEF lesions produced only temporary deficits in eye movements. Lynch [62] found that surgical removal of both FEF induced a dramatic impairment of visual pursuit in a behavior task consisting of visually tracking a moving target, while the monkey’s ability to produce accurate saccades was only slightly impaired. Schiller and Chou [63] showed that FEF ablation produced major and permanent deficits on tasks in which monkeys were trained to make saccadic eye movements toward targets presented at various temporal asynchronies, suggesting a major role of this structure in temporal ordering and processing speed for visually guided saccadic eye movement generation. Keating [64] confirmed that FEF ablation had a dramatic effect on visual predictive and nonpredictive pursuit. Interestingly, this effect disappeared 1–3 weeks after surgical removal in case of unilateral lesions, but reappeared after lesioning of the other in the contralateral hemisphere. As mentioned above, the effects of FEF surgical removal in humans have not been the target of specific reports. As a consequence, the few lesion studies conducted with patients presenting with ischemic stroke affecting the FEF are interesting to consider. From these studies [36, 65–68], reviewed and criticized by Vernet et al. [11], the general picture is that FEF lesions mainly affect voluntary saccadic movements, less reflexive ones.
3.4.2 On Visuospatial Attention It is known that FEF removal in monkeys provokes clinical manifestations very close to those observed in humans in case of unilateral spatial neglect. Welch and Stuteville [44] observed that lesioning a small area located in the depth of the posterior part of the superior limb of the arcuate sulcus (approximating the location of the FEF) caused unilateral neglect. Likewise, surgical lesion of the arcuate gyrus, at the caudal part of the principalis sulcus, induced nonsensory neglect (related to a defect of intentional behavior) in a study by Watson et al. [69], a conclusion that was reached by Valenstein et al. [43] based on the behavioral performances of monkeys following ablation of the arcuate sulcus. Watson confirmed that the ablation of the arcuate gyrus is associated postoperatively with neglect, but that the induced neglect is more severe when the lesion is accompanied with a corpus callosum disconnection [70]. To close this part of the chapter, it appears that surgical removal of the FEF in monkeys does induce abnormal oculomotor behaviors and impaired visuospatial processing, but the disturbances are more acute and long-lasting in the event of bilateral damage or when the corpus callosum is additionally lesioned. In our own
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clinical experience, the surgical removal of the FEF (which is very rare) or of its neighboring structures (which is frequent given the strong incidence of diffuse low- grade gliomas in the superior frontal gyrus) almost systematically induces a spatial neglect, albeit transitory, characterized by an inability to voluntary explore the contralesional visual field. From a neuropsychological standpoint, patients with such type of neglect fail to complete a cancellation task but perform well on a line bisection task contrary to patients with a parietal neglect who fail on both tasks (Fig. 3.4). These dissociable components of spatial neglect have already been outlined in a former study conducted with stroke patients, the results of which have prompted the authors to propose that neglect is a polymorph syndrome (see Chap. 4 and [71]). a
b
Fig. 3.4 Neglect signs following a surgical resection in (a) the right inferior parietal lobule (angular gyrus) or (b) affecting at least partially the right FEF (posterior dorsolateral prefrontal cortex resection with the precentral sulcus and the superior frontal sulcus as posterior and superior limits, respectively). In the latter case, only the cancellation task is affected whereas in the former both tasks are affected. Note that bells which are encircled in blue are items omitted by the patients. The right FEF is indicated by a white star. pDLPFC posterior dorsolateral prefrontal cortex, IFS inferior frontal sulcus, PrC precentral, SFS superior frontal sulcus
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Perspectives
3.5.1 W hy Searching for FEF Oculomotor Responses? Surgical Considerations Beyond the goal of avoiding long-lasting, and possibly highly debilitating impairments on visually guided behaviors, functional identification of the cortical FEF is very useful in finding the latero-posterior limits of resections concerning the posteriormost part of the superior frontal gyrus including the supplementary motor area as well as the supero-posterior limits of resections targeting the posterior part of the dorsolateral cortex. Likewise, identification of the oculomotor white matter pathway, likely forming a dedicated strata of the fronto-striatal tract [20], is one of the functional limits when operating in the deep matter of the dorsolateral prefrontal cortex. Of course, because the white matter of the dorsolateral cortex is an area where crosses at least four imposing white matter connectivities (i.e., fronto-striatal tract, frontal asltant tract, inferior fronto-occipital fasciculus, and superior longitudinal fasciculus branch II), other tasks are usually employed to map the white matter fibers surrounding the pathway projecting in the FEF, such as a mentalizing task in the right hemisphere ([72, 73]; see Chap. 18), a non-verbal semantic association task in both cerebral hemispheres ([74, 75]; see Chap. 15), or a motor task to map the negative motor network ([76–78]; see Chap. 1).
3.5.2 S hould We Use Other Behavioral Tasks to Map the FEF and Its Underlying White Matter Connectivity? In connection with the latter section, specific studies assessing neuropsychologically the behavioral consequences of FEF removal in humans are, to the best our knowledge, inexistent. Consequently, in the context of glioma surgery, it is unknown whether resection of the FEF as well as its neighboring and interconnected structures can lead to permanent and disabling impairments, in the left or the right hemisphere. Stated another way, although patients do not seem to present with chronic impairments, we currently do not know the exact neuroplasticity potential of this frontal area, contrary to nearest regions such as the supplementary motor area [79]. To provide insight into this important clinical matter, it would be especially relevant to plan a longitudinal study aimed at assessing the functional counterparts of FEF removal on oculomotor behaviors and spatial awareness and more generally on neuropsychological functions—before, immediately after, and a while after surgery. The results of this kind of well-controlled studies will allow to decide whether or not additional behavioral paradigms are needed to identify and spare subregions of the FEF not associated with ocular movements. At the present time, the FEF is indeed identified as such when ocular deviations, horizontal or more rarely vertical, are provoked. It is not beyond the bounds of possibility that other tasks may be considered, as visuospatial tasks gauging the voluntary component of visual attention, beyond the line bisection task which is useless because of its inability to
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capture the process of directed visuo-attentional exploration. In this respect, I am aware that some medical centers usually employed a cancellation task implemented in a touchscreen environment to assess this aspect of visuospatial attention at the whole-brain level [80]. However, once again, if patients recover spontaneously, it seems inappropriate to use such tasks at the risk of interfering with the onco- functional balance [81]. For example, in Charras et al. [82], 20 patients with a right diffuse low-grade glioma were assessed with a range of visuospatial attention tasks (including four cancellation tasks) the day before, 4 days after, and 3 months after surgery. Although half of the patients presented with visuospatial deficits, including exploratory deficits on the contralesional side, immediately after surgery, all of them fully recovered 3 months after surgery. However, no patients had a tumor around the FEF in this study, so the issue remains.
3.6
Conclusion
The FEF is a complex area interfacing between the oculomotor and the spatial attention systems. Until now, the FEF (and recently its underlying connectivity) was identified by observation of horizontal and sometimes vertical ocular deviations during direct electrostimulation. Although this mapping seems sufficient to avoid permanent deficits in the execution and regulation of oculomotor behaviors, it remains that there is no available evidence that patients did recover completely, especially with regard to higher level processes such as attention orienting, visual search, and awareness. It is thus advocated to mount studies, ideally longitudinally designed, to assess in a fine-grained manner the behavior performances of patients with a tumor damaging the FEF or areas situated in its vicinity. In the event of lasting and disabling impairments, then new tasks should be considered.
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4
Spatial Cognition Paolo Bartolomeo and Emmanuel Mandonnet
4.1
Introduction
During a walk, you want to cross a trafficked boulevard. You stop at a pedestrian crossing and watch the traffic light while waiting for the green pedestrian sign, while the cars are passing by. As soon as the green arrives, the cars stop and you start to cross, but at the last moment an unruly cyclist cuts you off: you narrowly avoid him. Your attention processes have allowed you to manage this situation in the best possible way, by selecting important information (voluntary attention on the traffic light) in order to maintain a finalized behavior (crossing the street) despite distractions. However, attention also allowed you to react quickly and appropriately to an unforeseen and potentially dangerous event (automatic attention captured by the cyclist).
4.2
Networks of Attention in the Brain
During the last decades, neuroimaging studies have provided extensive information on the neural implementation of spatial attention [1, 2]. Thanks to this work, we now know that there is no single region in the brain that manages attentional P. Bartolomeo (*) Sorbonne Université, Inserm U 1127, CNRS UMR 7225, Paris Brain Institute, ICM, Hôpital de la Pitié-Salpêtrière, Paris, France e-mail: [email protected] E. Mandonnet Sorbonne Université, Inserm U 1127, CNRS UMR 7225, Paris Brain Institute, ICM, Hôpital de la Pitié-Salpêtrière, Paris, France Department of Neurosurgery, Lariboisière Hospital, Paris Brain Institute (ICM) and Université de Paris, Paris, France e-mail: [email protected] © Springer Nature Switzerland AG 2021 E. Mandonnet, G. Herbet (eds.), Intraoperative Mapping of Cognitive Networks, https://doi.org/10.1007/978-3-030-75071-8_4
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processes. Instead, there are large-scale networks from the posterior (parietal) region to the anterior (prefrontal) regions of the brain. Although distant at the level of the brain, these regions communicate with each other quickly and efficiently, because they are connected by “brain highways,” large bundles of white matter (Fig. 4.1). These frontoparietal networks direct our attention in space, for example, towards the traffic lights before crossing the street. In general, each hemisphere of the brain directs attention towards the opposite side of space through a “dorsal” network of attention, including the superior parietal lobules, the frontal eye fields, and the dorsolateral prefrontal cortex (PFC). The pathway linking these regions is the dorsal branch of the superior longitudinal fasciculus (SLF I). However, an unforeseen and urgent event, such as the sudden arrival of the cyclist, can interrupt the current orientation and capture the subject’s attention. A second frontoparietal network deals with this important task of interrupting the ongoing attention activity, to redirect it to a new target. This second network is located lower in the brain and is thus defined as the “ventral” network of attention. It includes the inferior parietal lobule, its junction with the temporal lobe, and the ventrolateral PFC. These regions are connected by the ventral branch of the superior longitudinal fasciculus, SLF III. In most of us, the ventral network of attention is asymmetric between the cerebral hemispheres: it is mostly active in the right hemisphere (RH), the hemisphere non-dominant for language, and much less in the language-dominant left hemisphere (LH) [1]. More controversial is the possibility of a similar asymmetry for the dorsal attention network [6, 7]. An intermediate branch of the superior longitudinal fasciculus, SLF II, connects the temporoparietal part of the ventral attention network with the dorsolateral PFC, a node of the dorsal SLF I
SLF II
SLF III
DAN
VAN
Fig. 4.1 Frontoparietal networks in the monkey (left, from [3]) and in the human right hemisphere (middle, from [4, 5]), with the three branches of the superior longitudinal fasciculus (SLF I-III). Right: dorsal (DAN) and ventral (VAN) attentional networks in the right hemisphere according to Corbetta and Shulman [1]. Figure as originally published in Frontiers in Human Neuroscience 6:110, 2012 “Brain networks of visuospatial attention and their disruption in visual neglect,” by Paolo Bartolomeo, Michel Thiebaut de Schotten, Ana B. Chica. This is an open-access article distributed under the terms of the Creative Commons Attribution Non Commercial License https:// www.frontiersin.org/articles/10.3389/fnhum.2012.00110/full
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attention network [4]. SLF II thus allows direct communication between the ventral (SLF III) and the dorsal (SLF I) attention networks. A further, even more ventral network is connected by the inferior fronto-occipital fasciculus (IFOF), which links the ventrolateral PFC and medial orbitofrontal cortex to the occipital cortex, and thus allows top-down influence of PFC on visual areas. The IFOF network also shows anatomical signs of asymmetry favoring the right hemisphere [5]. The right ventrolateral PFC may thus constitute a convergence zone between the visual occipitotemporal stream [8] through the IFOF, and the ventral attentional network through the SLF III. In addition to these cortical networks, subcortical structures such as the superior colliculus and the pulvinar nucleus of the thalamus also play important roles in attention processes [9]. Other subcortical nuclei, the basal ganglia, contribute to attentional processing by modulating PFC influence on visual cortex. Specifically, basal ganglia activity has been found to enhance fronto-posterior connectivity with parts of the visual cortex that process attended visual information, and to decrease fronto-posterior connectivity with portions of the visual cortex that process unattended visual information [10].
4.3
isual Neglect, a Dramatic Clinical Consequence V of Attention Network Dysfunction
Given the paramount importance of attention in our daily lives, and the asymmetries of attentional networks favoring the RH, it is not surprising that the dysfunction of these networks in the RH can have serious consequences. For example, patients with brain damage may become unable to process several stimuli when simultaneously presented (as in extinction and simultagnosia), or stimuli arising in a region of space contralateral to the brain lesion (visuospatial neglect) [11]. In these cases, the “wrong” object (i.e., an object inappropriate to the current behavioral task) may win the competition and capture the patient’s attention [12]. Thus, when patients with left unilateral neglect are presented with bilateral objects, they compulsorily orient their gaze towards right-sided stimuli, as if their gaze were “magnetically” captured by these stimuli [13, 14]; afterwards, patients find it difficult to disengage their attention from these stimuli in order to explore the left part of space [15–19], so that their space exploration may remain confined to a few right-sided objects [20, 21].
4.3.1 Clinical Description Visual, or spatial, neglect refers to patients’ inability to orient their attention towards objects contralateral to their lesion (typically left-sided objects after right hemisphere damage). As a consequence, patients may behave as if the left part of the world did not exist anymore. This condition can occur in the absence of elementary sensorimotor deficits, and is severely disabling in patients’ everyday life. In the acute phase of a stroke, neglect can easily be detected by examining the posture and
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spontaneous behavior of the patients. They stay in bed with their heads turned to the side opposite to their hemiplegia (thus, most often towards the right side), and do not respond to stimuli from the opposite, neglected space (most often the left side). For example, if someone questions them on the left side, they may not answer, or they will respond to someone else on the right side. Any task involving vision leads to an even more exaggerated deviation of the gaze, towards the right-sided objects of the visual field. The deviation of gaze gradually disappears in the days following the stroke, but the tendency to be captured by right-sided items may persist in time. At this stage, other behavioral signs may become apparent. Patients do not wash the left side of their body; they may shave or make up only the right half of the face. They forget to put their left sleeve or their left shoe, let hanging the left branch of their glasses. Neglect is often manifest in the near extra-personal space. Patients can eat only the right side of their plate, read only the right half of the newspaper titles, without bothering about their lack of meaning. Once patients are able to perform neuropsychological tests, their behavior often remains confined to the right side of their visual space. Those of them able to stand up show disorders of the control of the posture, they may veer towards the left, probably because of impaired integration of visual, vestibular, somesthetic, or graviceptive information. Several weeks or even months after the onset of the lesion, a substantial proportion of patients manage to compensate for neglect both in their daily lives and during neuropsychological examinations. However, even in these patients, it is possible to detect more subtle signs of attention impairment. For example, they continue to begin their exploration of space from the right side [14, 22], while most healthy controls tend to start from the left side [23]—a phenomenon perhaps related to the combined influence of brain asymmetries of the attention networks and of Western left-to-right reading habits. When patients with compensated neglect produce manual or vocal responses to lateralized objects on the right or left, they respond more slowly to left-sided targets than to right-sided ones, particularly at the beginning of the tests, as if attention were initially captured by right-sided items [24].
4.3.2 Tests of Neglect Several paper-and-pencil tests can uncover these attention-related deficits [25]. It is very important to evaluate these capabilities in the clinic, because neglect signs can be clinically elusive; and yet diagnosis is essential because neglect patients should not be allowed to undertake activities requiring rapid reactions, such as driving for example. In addition, many of them do not fully recover from behavioral signs of neglect, which in turn can affect the recovery of their motor abilities [26]. Given the strong influence of stimulus position on neglect signs, it is important to carefully center the test sheets on the patient’s midsagittal plane. Not all patients consistently show neglect on all these tests, consistent with the multi-component nature of this syndrome [27, 28], with different patterns of deficits occurring in different patients [29, 30]. To achieve good diagnostic sensitivity, it is thus important
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to have patients perform several visuospatial tests. Neglect tests can schematically be classified in visuo-perceptual tests, visuo-graphic tests, and representational (or imaginal) tests. Visuo-perceptual tests are characterized by the fact that they do not require substantial motor activity towards a certain sector of space. For example, one may present patients with a lateralized version of the Wundt-Jastrow illusion [31], or ask them to identify overlapping figures [14], or to read a short text [25]. Typically, patients do not take into account information coming from the left half of the display: they do not suffer from a left-lateralized visual illusion, or omit to mention left-sided overlapping images, words, or letters. Visuo-graphic tests can be based on activities of copy, visual search, or line bisection (Fig. 4.2). Patients can be asked to copy geometrical or figurative drawings [33]. When copying, patients typically omit objects or details contained in the left half of the model (scene-based neglect). Sometimes, however, the patient can reproduce all the elements of the model independently of their spatial location, but neglect the left half of one or more items (object-based neglect). In visual search tests, patients are asked to find targets, such as lines [34], letters [35], stars [36], or bells [37]. Patients are asked to cancel out the target items, and typically omit to cancel left-sided targets. The difficulty of the task (e.g., when a target/distractor discrimination is a
c
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Fig. 4.2 Performance of a patient with left neglect on tests of copy (a), visual search (b), and line bisection (c). Figure originally published in [32]. This is an open-access article distributed under the terms of the Creative Commons Attribution Non Commercial License https://www.frontiersin. org/articles/10.3389/fnhum.2012.00110/full
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required) may influence the severity of neglect, as estimated by the number of left- sided omissions: the same patients tend to omit more targets with more difficult tasks [38]. In line bisection, patients are asked to mark the midpoint of horizontal lines. They typically misplace the bisection point rightward, especially when their attention is directed on the right extremity of the line [39]. Response time tests, analogous to those used to study spatial attention in normal participants, can provide more sensitive methods to detect subclinical biases in spatial attention [40]. For example, neglect patients often compensate for neglect on paper-and-pencil tests, but can remain slower in responding to left-sided targets than to right-sided targets [24], especially when engaged in a concomitant cognitive task, such as the inhibition of inappropriate responses [41]. Visual field defects, such as left homonymous hemianopia, can sometimes co- occur with neglect, for example, when lesions damage the optic radiations or the primary visual cortex. However, they can also occur independently of neglect. Importantly, hemianopic patients without neglect try to compensate for their deficit, often to the point of paradoxically deviating towards the left on line bisection [42], whereas patients with hemianopia and neglect deviate massively towards the right [43]. Goldmann perimetry can usually distinguish between hemianopia and neglect, because neglect patients without hemianopia are typically able to detect the single targets presented in their left visual field, despite their neglect. In rare cases, however, neglect can be so severe that patients can fail to report perimetry targets (pseudohemianopia). Presumably, the mere presence of the central fixation point can induce a stimulus competition with left-sided targets, which are then neglected. In one of these patients, removal of the fixation point just before target presentation was able to restore perception of left-sided targets [44]. The possibility of neglectrelated pseudohemianopia should be kept in mind especially with the now commonly used automated perimetry, where a trained perimetrist has less opportunity to interact with the patients and observe their performance. In case of doubt, lateralized ERPs can demonstrate the absence of hemianopia by showing normal response of primary visual cortex to left-sided checkerboards.
4.3.3 Models of Neglect It has long been recognized that left neglect is a typical syndrome resulting from RH lesions [45, 46]. Early models [47, 48] held that attentional neurons of the parietal lobe, charged with spatial surveillance function, could have bilateral receptive fields in the RH, whereas they would be limited to the contralateral half of the space in the LH. According to these models, there would be little or no neglect after LH lesions because the attentional neurons of the right parietal lobe (spared by the lesion) can detect the stimuli occurring in the ipsilateral space. There would, however, be neglect for the left half of the space after RH lesions because the attentional neurons of the left parietal lobe cannot monitor the left (ipsilateral) half of the space. On the contrary, Marcel Kinsbourne [49, 50] proposed that the basic asymmetry of neglect stems from LH preferential activation in verbally mediated tests. This left activation,
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accompanied by a trans-callosal inhibition of the right, contralateral hemisphere, automatically gives rise to an orientation of the gaze towards the right half of the space. These phenomena would be transient in normal subjects, but could become more stable (and thus result in left neglect signs) after right brain injury. Language activities (common in clinical tests) could further interfere with this general phenomenon, by activating the LH and causing a deviation of the gaze to the right. Neuroimaging evidence supported the Kinsbourne model, by showing a relative hyperactivation of the left superior parietal lobule as compared with its right hemisphere homolog in patients with left neglect [51]. The two structures reverted to a more balanced activity in the chronic phase, when signs of neglect had recovered. However, in the Corbetta et al.’s [51] study, other left attentional hemisphere structures, for example, in the PFC, had increased activity in the recovered phase as compared with the acute phase, thus suggesting a possible compensatory role of the undamaged LH [52]. Consistent with this mixed evidence, behavioral results did not offer definitive support for either of the rival models. For example, according to the Kinsbourne model when a group of patients with various degrees of left neglect produce speeded manual responses to left- or right-sided targets, their responses times to right-sided targets should decrease with increasing severity of neglect (as a result of increasingly stronger bias towards the right side); however, according to the Heilman/Mesulam models, these responses times should instead increase with increasing severity of neglect (as a result of less attentional resources deployed in both hemispaces). The results of such a study [20] showed that not only the responses to left targets, but also those to right targets became progressively slower as neglect increased, consistent with the hypoattention account. However, the two regression lines were not parallel. With increasing neglect, responses times to left targets increased more steeply than those to right targets did. Thus, a rightward attentional bias is present in patients with left neglect, together with left hypoattention. However, this rightward bias is one of defective, and not enhanced, attention. Also, neglect patients’ performance on perceptual estimation of line lengths [53] suggests that two independent deficits contribute to neglect signs: a deficit in attentional orienting to the left, perhaps depending on impaired functioning of RH attentional networks, and a tendency for attention to be captured by right-sided stimuli, possibly resulting from the activity of an isolated LH [54] .
4.3.4 Anatomy of Neglect Within the RH, the lesions responsible for neglect signs tend to localize in the posteroinferior portions of the parietal lobe [46, 55]. However, signs of neglect have also been reported in patients with lesions centered on the frontal lobe [56, 57], cingulate gyrus [48, 58], thalamus [59], and basal ganglia [56]. It is possible that these various focal locations have no special role per se [60], but instead result in network-based dysfunction of the attentional circuits, especially those linked by SLF II and III (recent reviews in [11, 61, 62]). Also, more ventral damage to the right-lateralized IFOF has been associated with neglect [39, 63, 64]. However, as
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mentioned before, damage to the LH homolog regions only rarely results in rightsided neglect [25]. Signs of right-sided neglect have been observed after bilateral hemispheric damage, whether due to vascular strokes [65, 66] or to neurodegenerative conditions [67, 68]. This finding might indicate the necessity for some degree of RH dysfunction even for signs of right-sided neglect to occur. The right-lateralized SLF III network is a possible candidate site of RH dysfunction in patients with right-sided neglect [7]. As detailed in the previous section, an important aspect of left neglect behavior is a bias to explore the right portions of extra-personal space. In experimental settings, this bias often translates to the production of “inappropriate” rightward saccades, i.e., saccades towards nontarget right-sided stimuli. Eye movement recordings showed that this tendency could not be completely overcome by endogenous orienting of attention, and was related to damage to SLF fibers leading to the RH FEF [13]. Recent lesion-symptom mapping studies of neglect have confirmed the presence of damage to SLF II-III and IFOF networks in the RH [64, 69–73]. Recent electrophysiological studies suggested a relative sparing of PFC activity in neglect patients. Activity in LH PFC might actually be causally related to neglect omissions: a MEG study demonstrated a specific increase of low beta synchronization activity in left frontal cortex before omissions of response to left-sided targets [74]. In an ERP study, attention-related PFC activity was preserved, but unable to counterbalance deficits in parietal-occipital activity [75]; however, in other patients PFC activity correlated with intentional, compensatory gaze shifts towards the left, neglected side [76]. Recovery from neglect has been related to the state of inter-hemispheric connectivity with the left, undamaged hemisphere [77, 78]. Evidence from diffusion- based MRI suggested an important role of the caudal portions of the corpus callosum, which connect the posterior nodes of the attentional networks, perhaps because the undamaged LH needs some access to information processed in the damaged RH to compensate for neglect signs [77, 79]. The status of more rostral portions of the corpus callosum can predict response to rehabilitation therapies such as prism adaptation: patients with chronic neglect and caudal callosal disconnection, but intact body and genu, were more likely to respond to prism adaptation therapy [80]. Prism adaptation could thus promote inter-hemispheric integration through these callosal connections (Fig. 4.3).
4.3.5 Postsurgical Neglect Studies reporting postoperative unilateral spatial neglect after a surgical resection are scarce. We summarized in Table 4.1 a comprehensive review of the literature. We found no more than 22 cases (in eight studies: [81–88]) with signs of left spatial neglect in the immediate period (
Supramarginal Gyrus (SMG)
Ventral | Dorsal Premotor (v|dPM)
Anterior Intraparietal sulcus (aIPS)
Posterior Middle Temporal Gyrus (pMTG)
Intraparietal sulcus (IPS)
Lateral Occipital Cortex (LOC)*
Medial Fusiform Gyrus | Collateral Sulcus
n = 38, FDR q < .05
*Based on contrast of intact images (all categories) > phase scrambled images
Fig. 11.1 Functional MRI has been used to delineate the neural substrates of the neural regions that support recognition and use of tools. The data shown in the figure were obtained while participants viewed tool stimuli compared to images of animals and faces. Regions are color-coded to distinguish what are functionally dissociable regions, as documented in the neuropsychological literature. (Figure reproduced, in part, from Mahon [25], with permissions)
purposes is whether (and if so, how) this broader network of action areas figures causally in visual confrontation naming of tools and other manipulable objects. While the neuroimaging evidence is clear in that motor and motor-relevant areas in left parietal and frontal areas are automatically engaged during naming of tools, the available neuropsychological data indicate that tool naming can be preserved in the setting of damage to the same areas [31–33]. People with lesions to left parietal or premotor areas can present with limb apraxia (among other, nonaction, impairments), but can still be able to name the same objects they are unable to use correctly (provided the lesion does not involve the speech production systems) [31– 33]. The dissociation between impaired action production and spared naming indicates that the ability to conceptually individuate an object does not require implicit motor simulation of the action associated with the use of the object. This frames the need for hypothesis-driven direct electrical stimulation mapping to evaluate whether transient disruption of those fronto-parietal structures specifically affects naming of graspable objects. By contrast, there is compelling evidence from both activation and lesion studies that the left posterior middle temporal gyrus plays a decisive role in supporting recognition and understanding of actions, and objects that are associated with actions [34–36]. Lesions involving the left posterior middle temporal gyrus can lead to naming impairments that are differentially profound for tools compared to other categories (e.g., animals, vehicles), and for action concepts [15, 29, 37–39].
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Biological entities There is a rich neuropsychological tradition of studying dissociations by semantic category within the broad category “nouns” [40–42]. About 150 well-studied neuropsychological cases have been described with conceptual level deficits that are differential or selective for one of the categories of fruit/vegetables, animals, nonliving things, or conspecifics (i.e., familiar faces and people) [43]. The evidence that the deficit in such patients is to conceptual knowledge (e.g., word and object meanings), as opposed to perceptual input (e.g., early visual/auditory processes) or linguistic output representations (e.g., word retrieval, phonological encoding), is provided by the boundaries of the impairment. Patients with category-specific semantic impairments have problems accessing knowledge about the impaired category independent of the format of the stimulus or the required response. For instance, such patients may be impaired at naming, but also at identification tasks that do not require a naming response, such as matching tasks like the Pyramids and Palm Trees test (see Chap. 15 and reviews in [23, 44]). Similarly, such patients can be impaired for knowledge about the impaired category regardless of whether that knowledge is cued through a picture or a spoken or written word. This is in contrast to, for example, a category-specific visual agnosia, such as prosopagnosia, for which patients have a category-specific deficit specifically for visual recognition but have not otherwise lost knowledge about the same category [45, 46]. While it is far from a universal generalization [47, 48], one pattern that emerges is that impairments with biological entities are often associated with damage to temporal lobe areas, in particular anterior basal and medial structures such as are affected in semantic dementia and herpes simplex encephalitis [49, 50]. This includes patients with impairments affecting animals [51], plants, and fruit/ vegetables [52], as well as loss of knowledge of other people which is generally associated with right anterior temporal lobe injury [53–58]. In partial agreement with these studies, Papagno and colleagues [59] report DES positive sites in the temporal lobe and inferior frontal gyrus for naming living objects, while stimulation to other areas in the posterior third of the supramarginal gyrus and possibly the arcuate fasciculus induced more errors for nonliving things. A related topic is the involvement of nouns referring to names of famous people in the anterior temporal lobe and subcortical structures, particularly, the uncinate fasciculus [59]. A topic that seems interesting to explore is whether the role of this subcortical structure is specific to names of famous people or includes other proper name categories, including individual-specific person name knowledge (e.g., surnames, first names, nicknames), geographical names (e.g., cities, countries, rivers), and names of commercial brands, books, paintings, and events (e.g., [53– 57, 60]). Action recognition and naming A critical aspect of the neural basis of action naming is the neural circuitry involved in action recognition and understanding. At the broadest level, actions are intentional movements of the body that satisfy a goal (e.g., we move the hand “to peel” a pear, or move the leg “to kick” a football). Both noninvasive and invasive neural and/or neuronal recording techniques demonstrate automatic engagement of perceptual areas, and pre- and supplemental motor areas
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during perception and recognition of actions [61–63]. In a similar vein, reading verbs related to different parts of the body such as the hand (e.g., “peel”), the mouth (e.g., “bite”), or the feet (e.g., “kick”) drive activity in motor and motor-relevant areas [61–63]. The question is what functional role do motor production processes play in recognition and naming of actions. A currently popular interpretation of such findings [64] derives from the idea of “analysis by synthesis” [65, 66]—in order to recognize an action, the processes involved in production of the same action are internally (implicitly and automatically) simulated. For example, when naming the action “to cut,” the motor areas that support the action of “cutting” at the level of the hand are active. There has been a lot of interest in the concept of motor resonance and motor simulation, including critical discussions of the proposal [67–71]. Neuropsychological data can play a decisive role in evaluating the role(s) of action/motor processes in frontal and parietal areas in supporting action recognition and, more broadly, processing of words referring to actions. On the one hand, TMS studies [72, 73] and some patient studies [74, 75] have indicated action recognition impairments subsequent to (transient or chronic) lesions involving motor areas. On the other hand, patients can be impaired at action production but spared for action recognition. This has been observed in the setting of arm actions [32, 76, 77] and speech processing [78, 79]. Those types of patient-based findings indicate that even when motor output processes are damaged and patients are unable to produce actions in the first person, they can still recognize the same actions (for reviews, see [80–83]). In simpler terms, a person may be unable “to cut a piece of paper” but would understand the meaning of “cutting” when seeing a picture or reading a word. The implication is that while motor and motor-relevant structures are active during naming, it seems that those motor processes are not strictly necessary in order to name actions. This motivates hypothesis-driven DES studies to evaluate whether disruption of fronto-parietal structures specifically affects action naming compared to (a) nonaction events, and (b) actions outside the human action repertoire (e.g., “she jumps” vs. “the window breaks” vs. “the bug bites”). Verb argument structure Another issue to consider when assessing the integrity of verb knowledge is verb argument structure. Transitive verbs like “eating” take an object (e.g., Mary eats an apple, where “an apple” is the object) and are different from intransitive verbs such as “sleeping” which do not take such an argument (e.g., Mary sleeps). Neuroimaging studies have suggested that transitive verbs have further representation in the posterior part of the left superior temporal gyrus (e.g., [84–86]) This evidence is reinforced by lesion studies where people with post- stroke aphasia typically have more difficulties producing verbs that have more arguments (See Fig. 11.2) [87–89]. Arguments for the difference between these two types of verbs often note that transitive verbs require more complex computations than intransitive verbs in order to be expressed. Different theories emphasize different aspects of transitive and intransitive verbs. If we take a sentence with a transitive verb like “Mary eats an apple” and a sentence with an intransitive verb like “Mary sleeps,” the differences
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Fig. 11.2 Cortical representation of transitive and intransitive verbs in the left and right hemisphere. Green: Areas reported to be significantly more activated with transitive verbs. Yellow: Areas that have been reported to be significantly more activated with intransitive verbs. Blue: Areas that have been reported to be significantly more activated with both verb types
include: the amount of specified arguments (e.g., having an object like “apple” or not having an object); thematic roles (e.g., “Mary” as the agent or doer of the action of eating, and “apple” as the theme or entity that is affected by the action; compared to “Mary” as the experiencer or entity undergoing the action of sleeping); and the subcategorization frame (e.g., the lexical entry of the verb “to eat” takes two arguments with a noun phrase that functions as a subject, i.e., “Mary,” and a noun phrase that functions as an object “an apple”; the lexical entry of the verb “to sleep” which can express only one event which involves one participant, namely, a noun phrase that functions as a subject, i.e., “Mary”) [90, 91]. With respect to neural correlates of verb argument structure, it has been argued that there is a positive relation between the number of regions recruited and argument structure complexity. That is, further tissue is recruited to integrate the verb and its arguments into the syntactic structure of the sentence. In that sense, it may be hypothesized that transitive verbs should rely more heavily on posterior regions, as opposed to intransitive verbs [86, 92]. To summarize our arguments on the neural basis of nouns and verbs, studies indicate a general tendency for partial overlapping between cortical areas and less evidence for differentiation at the subcortical level. The partial consistency between lesion and neuroimaging studies may relate to factors such as the spatial and temporal resolution of each of the methods, the varieties of tasks/paradigms that can be used to assess object naming, and detecting areas that support and/or are essential for each of its functions (e.g., object recognition, semantic access, lexical retrieval, articulation). In this section, we argued for the use of potential differences between nouns and verbs. This emphasizes the differences within types or characteristics of nouns and verbs in order to gain new leverage on approaches for intraoperative mapping. These differences can advance understanding of how nouns and verbs are processed in the brain, while also increasing the sensitivity and specificity of language mapping, in line with the goals of the brain mapping in a neurosurgical setting. Two of the topics we reviewed indicate that words with strong sensorimotor associations (e.g., graspable objects and actions) automatically activate sensorimotor areas during a naming task. In the same vein, a related constellation of findings points to this being a relatively broad phenomenon and not limited only to the action
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domain: nouns with strong gustatory (“salt”), olfactory (“jasmine”), and auditory associations (“telephone”) drive activity in sensory brain regions related to taste (e.g., anterior insula, frontal operculum, lateral orbitofrontal gyrus, thalamus), smell (e.g., piriform cortex and amygdala), and audition (Heschl’s gyrus) (for the original theoretical precedent, see [93]; for recent empirical studies, see [94–98]). And similarly, nouns with strong motion properties (e.g., car) differentially drive activity in the vicinity of motion sensitive area MT/V5 in posterior-lateral temporal cortex [99]. However, the available neuropsychological evidence forms a pattern in that disruption of the same structures that are automatically engaged does not necessarily disrupt naming performance—thus it remains an open question whether DES to sensory- and motor-specific structures may disrupt naming of the corresponding word types.
11.3 E vidence of Long-Term Deficits in People Who Did Not Benefit from Intraoperative Language Mapping with Naming Tasks with Nouns and/or Verbs Here we highlight four studies in which patients were operated on with intraoperative object naming but not action naming (nonfinite forms, e.g., “jumping”), and three studies where patients were operated on with intraoperative mapping that involved both object and action naming. To the best of our knowledge, there are no studies in which only action naming, or only tasks with verbs, have been used for intraoperative mapping. With respect to studies for which only object naming was administered, Santini and colleagues [100] studied the perioperative results of 22 people with low- and high-grade gliomas and reported a decline in naming scores immediately after surgery (within a week after surgery), with recovery at follow-up (3–6 months after surgery). The authors indicated the same pattern for other language tasks. Unfortunately, both object and action naming scores were combined as one measure of naming; hence, it is not possible to assess whether action naming was more impaired than object naming. Nonetheless, the authors showed scores below the normal level on word fluency, verbal working memory, and immediate recall of words—all of these being tasks that require language processing (along with other cognitive functions). Satoer and colleagues [101] looked at 45 people with low- and high-grade gliomas, mostly in the perisylvian regions of the left hemisphere. The authors studied the scores of people who underwent surgery without action naming, before surgery, 3 months after surgery, and 1 year after surgery. Similar to Santini and colleagues [100], the authors reported issues in word fluency and immediate recall of words. Also, they reported problems in attention, executive functions, and object naming— the latter resolving 1 year after surgery. In this study, action naming scores were not reported. In another longitudinal study by the same group, Satoer and colleagues [102] reported spontaneous speech impairments in 18 people with low- and highgrade gliomas, also 3 months and 1 year after surgery. The majority of those patients
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were assessed intraoperatively with object naming and repetition, not necessarily with action naming. Interestingly, the authors reported issues with spontaneous speech that relate to lexical-semantic and morphosyntactic impairments; these aspects of linguistic computation would arguably be well mapped with action naming and, particularly, action naming with finite verbs. Norrelgen and colleagues [103] reported findings from 27 people with a low- grade glioma or cavernoma in the left hemisphere. All patients underwent surgery with object naming but not action naming. Relative to preoperative scores, patients declined in animal and verb fluency at 3 and 12 months after surgery. Five people had impairments on object naming before surgery, but none of the patients had below-normal scores on object naming or sentence comprehension at follow-up. With respect to studies where both object naming and action naming were used, Papagno and colleagues [104] reported preoperative data from 226 people operated on for a low- or high-grade glioma. Of those, 117 were assessed 3 months after surgery. The data are presented as percentages and participants are divided by brain area. Higher percentages of people were impaired for object naming and action naming before surgery than at follow-up. A number that is particularly striking is that 40% of people with lesions in the left parietal lobe were impaired for action naming before surgery, but only one participant presented with below-normal scores 3 months after surgery. Other than that, there is an increase of about 20% in the percentage of people with lesions in the left frontal lobe whose scores are impaired for phonemic fluency after surgery. Similar results were reported in a recent study that used a similar testing protocol and included 102 people with high-grade gliomas [105]. In contrast, Pisoni and colleagues [106] reported the perioperative results of 102 people with a high- or a low-grade glioma in either the left or right hemisphere. Interestingly, postoperative results 1–7 days after surgery revealed new action naming impairments in nearly 30% of the people, the majority of which had tumors in the left hemisphere. In summary, while the literature remains sparse at present, postoperative testing in people with brain tumors who underwent intraoperative mapping with object naming, or with both object and action naming, do contain some language impairments, particularly, in tasks that tap into lexical-semantic and morphosyntactic processes. Fluency tasks have been shown to be impaired, along with object naming, and sometimes action naming. When both object and action naming tasks have been used intraoperatively, two studies report an increase in new impairments in action naming and a third a decrease, at least for lesions in the left parietal lobe, an area known to be involved in the processing of action verbs (see Sect. 11.1 above). Further work is needed to understand for how long after surgery such impairments remain, if the incidence is higher when object naming alone is used during intraoperative language mapping, and how these impairments impact in quality of life. With respect to the latter point, a study examining both accuracy and response times would be valuable, similar to the report on object naming latencies and return- to-work by Moritz-Gasser and colleagues [107]. Further work on spontaneous speech could also be valuable, given the correspondence between formal testing and spontaneous speech in people with brain tumors (see Chap. 6 and [102, 108]).
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11.4 Knowledge Gained from Lesion-Symptom Mapping To our knowledge, only two studies have carried out lesion-symptom mapping with both object and action naming in people with brain tumors. Both studies included nearly one hundred Italian-speaking people with either a low- or a high-grade glioma. Pisoni and colleagues [106] looked at pre- and early postoperative results (1–7 before/days after surgery) in individuals with tumors in the left and right hemisphere, while Tomasino and colleagues [109] only considered preoperative results (1 week before surgery) and people with tumors in the left hemisphere. The results of both studies stress the role of the left hemisphere. With respect to the representation of objects, Pisoni and colleagues [106] stress the role of the anterior temporal lobe, whereas Tomasino and colleagues [109] discuss the role of basal temporo-occipital regions (see also Fig. 11.1). As discussed above (Sect. 11.1), both of these regions are known to support dissociable components of object knowledge that is accessed during naming. With respect to actions, both studies agree on a role of left parietal cortex for the production of action verbs. What is less clear is the involvement of the left frontal lobe (reported only in Tomasino et al. [109]) and the temporal cortex (only posterior aspects are reported in Pisoni and colleagues [106], while broader areas are reported in Tomasino and colleagues [109]). The involvement of subcortical pathways is also unclear, in that one study specifically reported finding no pathways [106]. However, Tomasino and colleagues reported involvement of the superior and posterior corona radiata and the inferior fronto-occipital fasciculus for actions, while the inferior longitudinal fasciculus, corpus callosum, thalamic radiation, internal capsule, and fornix were implicated in processing of objects [109]. These results for people with brain tumors are not entirely in agreement with a similarly powered study of people with left-hemisphere stroke [110]. In that study, impairment in object naming was associated with the anterior and posterior middle temporal gyrus, superior temporal gyrus, and inferior parietal cortex. Interestingly, when controlling for impairments in articulation and visual recognition, the left middle posterior temporal gyrus and underlying white matter appeared to play a critical role in object naming (see also [29]). Adding to this literature, an earlier less powered study in individuals with left-hemisphere stroke found that the inferior frontal gyrus and the anterior part of the temporal lobe were relevant for action naming [111]. In a similar study that considered different neurological populations (mostly stroke) and a variety of tasks tapping on verb processing [15], the role of the inferior frontal gyrus was also stressed. However, the anterior part of the temporal lobe was argued to not be essential for representing or processing action concepts, since a number of patients they studied who underwent anterior temporal lobe surgery for epilepsy were not impaired for tasks involving actions. Findings with lesion-symptom mapping in people with brain tumors warrant replication in other languages, as currently available studies were conducted in Italian. For example, it would be interesting to cross-validate the results in typologically similar languages, such as French, Spanish, and Catalan, as well as to look for
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potential differences in languages that are rich in morphology such as Korean and Turkish, and languages with impoverished morphological markers such as English or Chinese. This is because, differences could emerge between languages that have verbs that engage more or less in morphosyntactic processes (e.g., [112]). Nonetheless, we expect action naming to be, on average, more impaired than object naming, as this is the case even in languages with poor morphological inflection (e.g., [113]). This is possibly because, even when we disregard morphological processes, verbs are key elements for structuring sentences (e.g., they specify arguments, thematic roles, have a subcategorization frame, are useful to refer to the time when the event happened), while nouns refer to concepts and are dependent on verbs to “make sense” in a sentence (e.g., “John ate pasta” vs. “John is eating/ cooking pasta”). Future work could also consider running similar analyses for naming actions with finite verbs (e.g., she runs), as the use of finite verbs taps into morphosyntactic processes, which may index a broader set of linguistic computations than nonfinite verbs (e.g., to run, running) or nouns [114]. Finally, the studies we reported include behavioral data at a preoperative stage or at an acute stage early after surgery (~1 week). In this sense, the performance of people at a more chronic stage such as three to six or even more months after surgery could contextualize early postoperative deficits that may not be as specifically related to the location of the surgical resection per se, but to more general consequences of neurosurgical interventions (e.g., early presence of edema, decompression of tissue around the surgical cavity [115]). There are also important limitations associated with lesion-symptom mapping that should be considered: First, whereas the lesion, at least defined for analytic purposes, is a static variable for any given individual, performance levels are dynamically changing along the timeline from preoperative assessment to subacute to chronic assessment; thus, for the same lesions in a group of patients, the lesion-behavioral correlates can change quite dramatically depending on when patients are tested over the trajectory of their recovery [116–118]. Second, the effect of the lesion on behavior is due not only to the tissue that is physically lost to the lesion but also to tissue that was part of a functional network with the lesioned area [119]. Lesions to one region will disrupt information processing for computations in other regions that depend(ed) on the lesioned area for inputs or outputs [120]. In a recent study of preoperative tumor patients [121], it was found that functional MRI responses in basal temporal structure (fusiform gyrus, collateral sulcus) were modulated by the presence of lesions to parietal cortex. This relation was category-specific, in that fMRI responses in the fusiform gyrus were modulated only for tools by lesions to parietal cortex, while responses to places, faces, and animals were unaffected. That finding was interpreted in terms of the need for tools (compared to places, faces, and animals) to integrate visual representations of surface structure and texture (processed by medial basal temporal lobe structures) with motor-relevant properties of the use of the objects (parietal cortex).
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Third, these issues are compounded in the setting of tumor patients, as there could be reorganization of function during the period when the tumor was growing. The result is that the behavioral performance level for a given task may not be what would be predicted were an otherwise typically developed individual to have a sudden onset of a lesion in the same location as the tumor. Herbet and colleagues [122] reported a case series in which some of the patients had a low-grade glioma in the left anterior temporal lobe, while in others, this brain area was not involved with tumor. All of the patients underwent an awake craniotomy with language mapping, and specifically DES of the inferior longitudinal fasciculus (ILF) in the dominant hemisphere. The authors found that stimulation of the ILF caused anomic errors, but only in patients who did not have long-standing pathology in the anterior temporal lobe. The implications of these findings are that (1) the ILF does play a critical role in language processing, and specifically naming; and (2) if tumors have infiltrated the left anterior temporal lobe, there is reorganization of the language network (such that stimulation of the ILF no longer disrupts naming). Future systematic investigations such as reported by Herbet and colleagues will be critical for understanding plasticity, reorganization of function, and redundancy of functional pathways.
11.5 Tasks Newly Designed to Map Language Marla Hamberger and colleagues [123–128] explored a different paradigm within noun production that does not depend on the targets being picturable—the authors refer to this paradigm as “auditory naming”; more generally, it is a form of definition naming or naming to description. For instance, the patient listens to a short description: “The yellow part of an egg” (answer: yolk) with stimulation being applied during the period that the patient is presented with the definition. Those authors found that auditory definition naming, and not visual/picture naming, identified essential language sites in the anterior temporal lobe [123]. A subsequent study by the same group investigated language outcome in people undergoing temporal lobe surgery in whom both picture naming and auditory naming were used to define essential language sites intraoperatively [126]. The key point of comparison concerned resections that avoided essential language sites identified with picture naming (i.e., the clinical standard), but did not avoid essential language sites identified with auditory naming. The authors found increased word finding difficulties in people who had auditory-naming-defined essential language sites resected, compared to people without resection of auditory naming sites. For ethical reasons, there was no comparison group where visual/picture naming-defined essential language sites were resected. Interestingly, the postoperative deficits observed in people with auditory-defined language sites resected were observed both in auditory naming and in picture naming. The discussion about the most effective tasks for identifying essential language sites in the anterior temporal lobe continues [8, 9, 123, 126, 129–132]. Hamberger et al. [123, 126] emphasized the auditory nature of the stimuli and suggested an
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auditory representational code in the anterior temporal lobe. Subsequent research and theoretical proposals argued that the anterior temporal lobes represent amodal conceptual information [133–138]—in which case the modality of the cueing stimuli (auditory, visual) would be expected to matter less [69, 139–143]. Another important issue is that experimental paradigms in which pictures, as opposed to auditorily presented definitions, are used to cue word retrieval may allow for additional and parallel pathways to a target name from the stimulus (picture). Anatomically, such redundant pathways could be (1) right hemisphere identification processes that bypass left anterior temporal semantic representations, and access words via callosal projections (for evidence from split brain patients, see [144, 145]), and/or (2) projections that connect occipital and frontal naming sites and bypass the anterior temporal lobe (e.g., the inferior frontal occipital fasciculus [116, 146–148]). Following the aforementioned work on naming to definition, a novel way to administer verb naming could be by providing participants a short description of the verb (e.g., what do we do with a book, “reading”). This version of the task may engage auditory processes to segment strings of sounds into words as well as understand grammatical information. This is distinct from using line drawings, as picture naming requires visual perceptual analysis and other perceptual processes (e.g., [149, 150]). To the best of our knowledge action naming to description has not been used intraoperatively. Clinicians and researchers implement action naming and naming tasks with finite verbs with the help of line drawings, color pictures, or short vignettes [151– 154]. The most common approach uses line drawings, following the tradition of intraoperative mapping with object naming [154]. The way in which the tasks are administered seems relevant, as different methods engage different language functions. For surgical mapping, it has been argued that vignettes (e.g., a person peeling a banana or cracking an egg) are more natural depictions of actions and, hence, more ecologically valid than line drawings [151]. However, this study did not compare the two types of stimuli but rather used vignettes instead of drawings. Further inspiration for the type of stimuli that could prove useful for intraoperative mapping may be found in the psycholinguistic and post-stroke literature. For example, Salmon and colleagues [155] found that manipulable objects (e.g., “banana,” “hammer”) are named faster by healthy individuals when presented as photographs compared to black-and-white line drawings. Interestingly, the authors reported no difference between photographs and black-and-white drawings, when the items were non-manipulable objects (e.g., “pigeon,” “staircase”). Consequently, if the amount of visual detail in photographs facilitates the retrieval of nouns that require “bodily movement,” it may also be argued that action verbs (e.g., “cutting” vs. “sleeping”) may be produced faster and more accurately when presented as pictures, as opposed to black-and-white drawings. The extent to which this type of work may affect peri- and intraoperative results in people with brain tumors is unknown. However, it seems relevant to consider, as it could help minimize intraoperative false positives.
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A key issue, when considering how to generalize observations to broader groups of patients, is whether the group of patients in question is homogenous in terms of the neurocognitive processes affected by the lesion. For instance, the picture-naming performance of people with impairments to earlier levels of processing (e.g., picture recognition, due to posterior temporal or occipital lesions) will be affected by manipulations to the format of the visual stimuli. However, people with impairments to other levels of processing, such as peripheral phonological problems or lexical-semantic impairments, may perform the same regardless of manipulations to the input, but may be affected by output dimensions (e.g., word length). This emphasizes the need to develop explicit hypotheses, up front, about the nature of computations believed to be supported by a brain region. Therefore, it is critical to not interpret clinical categories such as “post-stroke” aphasia too seriously without further examination, as the patients subsumed under that label will be heterogenous in terms of the underlying mechanisms affected by the injury [156]. Similar arguments should also hold when considering postsurgical cases. It should be noted that even though for action naming the final output is a verb, there exist significant differences between producing a verb in a nonfinite form (e.g., “reading,” “to read”) and producing a verb in its finite form (e.g., “she reads”). When producing a verb in the finite form, there is agreement over the fact that a subset of the processes necessary to produce a sentence are needed, thus engaging the retrieval of the word (lexical retrieval) as well as grammatical processing (e.g., subject-verb agreement, reference to time, use of tense). However, when producing a nonfinite form, while it is clear that lexical retrieval is involved, it is not as clear whether the same grammatical processes are obligatorily engaged [11, 157]. The engagement of those grammatical processes is consequential for the regions that will be recruited (e.g., [112, 157]), and also renders the task sensitive to processes that are involved in the use of language on an everyday basis (i.e., spontaneous speech, see Chap. 6 and [114]). A study comparing pre-, intra-, and postoperative mapping of action naming with nonfinite verbs and finite verbs, as well as more general measures of language, would shed light on these issues. Finally, action naming tasks were discussed in early reviews of tasks to be used for intraoperative language mapping [158], and are currently included in protocols in numerous languages including English [159], German [159], Russian [160], Dutch/Flemish [159, 161], and Italian [162, 163]. Some of these versions are particularly interesting, as they include ratings for a number of word properties such as frequency, imageability, age of acquisition, and other variables [149, 150, 164]. Controlling the items for such properties may be relevant at the preoperative level, to have a better understanding of which language functions may be impaired, as well as to understand whether specific subsets within word types are differentially affected (e.g., low frequency items). All of this is also relevant to tailor the tasks to the capacities of each individual patient; for example, instead of removing single words that a person may have problems with, it may be possible to remove a whole word type (e.g., intransitive verbs). This approach could also help diminish the number of intraoperative false positives.
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11.6 F unctional Improvement in Patients Engaged in Intraoperative Naming Task with Nouns and/or Verbs Compared to Patients Not Studied with Those Tasks The administration of action naming and naming finite verbs has been argued to provide intraoperative maps with more and different positive cortico-subcortical areas, particularly when compared with object naming (e.g., [19, 20, 130, 151– 153]). To our knowledge, there are no studies providing evidence in favor of the unique administration of action naming or finite verbs for intraoperative language mapping. Rather, researchers and clinicians advocate for an approach with both action naming and object naming. It could be that the combination of the two tasks allows for more reliable mapping of cortico-subcortical areas and language processes that are engaged in everyday language abilities—particularly when using finite verbs [114]. However, this hypothesis has not been directly tested by prospectively manipulating the inclusion (versus not) of finite verb naming. It is difficult to find reports stating that there is a functional improvement in patients mapped intraoperatively with action naming only, as opposed to other mapping approaches such as object naming alone. Indeed, at this stage, it seems unethical to assess patients only with action naming, particularly when many teams advocate for a combination of tasks and when the current gold standard is object naming (e.g., [130]). In this regard, if the goal is to understand functional improvement, it could be relevant to study the perioperative relation between different tasks used in awake surgery and scores on functional tasks (e.g., such as spontaneous speech, everyday communication scales, questionnaires, or quality of life measures). This is relevant to assess whether a task used during surgery engages processes required for everyday communication (e.g., [114]). Likewise, in the domain of language, we are unaware of studies that have assessed postoperative performance when other tasks were used instead of object naming. However, it seems evident that operating on the patient awake with object naming is preferable to an asleep surgery without language testing [165].
11.7 A dditional Anatomo-Functional Knowledge Gained from Intraoperative Mapping Studies At the cortical level, intraoperative mapping studies have provided information that is not much different from lesion studies or studies with neuroimaging techniques. That is, there exist a number of brain areas in left perisylvian areas that are involved in naming tasks with objects and verbs, with substantial variability across participants (for reviews of intraoperative results, see [8, 22]). Important in this context, future intraoperative mapping studies can provide unique insight regarding the role of subcortical structures in supporting these tasks. An example of the types of inferences about subcortical pathways that are afforded by stimulation mapping is provided by two case studies that focused on the
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recently described Frontal Aslant Tract, which connects the inferior frontal gyrus with pre-supplementary motor cortex [166]. One study used subcortical stimulation of the Frontal Aslant Tract while the patient was engaged in a controlled sentence production task designed to have sensitivity to subtle disruptions to sentence planning [167]. The patient was engaged in producing sentences such as “The red triangle is above the yellow circle” where the color and shapes varied from trial to trial and were cued via a visual stimulus. It was found that stimulation of the Frontal Aslant Tract disrupted sentence production specifically at the boundaries of grammatical phrases (i.e., in the example above, after the determiner phrase “the red triangle,” or before the determiner phrase “the yellow circle”). Those intraoperative findings were in agreement with a prior case report of a patient, whose left middle frontal gyrus tumor required partial resection of the Frontal Aslant Tract, and for whom postoperative spontaneous speech was marked by substantial hesitations at the boundaries of grammatical phrases [168]. The authors suggested findings from those two studies frame the hypothesis that the Frontal Aslant Tract supports mapping from the grammatical structure of sentences (inferior frontal gyrus) to linearized surface forms required for motor planning (anterior supplementary motor cortex)—referred to as the Syntagmatic Constraints on Positional Elements (SCOPE) hypothesis [167, 168]. For instance, in the sentence “The boy ate the apple,” the representations of the subject (boy) and object (apple) are processed together within the overall thematic structure of the sentence at a semantic and grammatical level; however, at the level at which the sentence is articulated, “boy” and “apple” are computationally separated in time. The idea is that the FAT maps between the structural form of the sentence and its surface form. With respect to tasks with verbs, Lorenzo Bello’s group [19, 20] reported involvement of different portions of long association fiber pathways (e.g., arcuate fasciculus, superior longitudinal fasciculus, uncinate fasciculus, inferior fronto-occipital fasciculus) in action naming (with nonfinite verbs). Rofes and colleagues [130] also reported the involvement of subcortical pathways in action naming with finite verbs, particularly the anterior part of the arcuate fasciculus and the inferior fronto-occipital fasciculus [19, 20]. Further work is needed to understand the cortical and subcortical representation of currently used tasks via intraoperative mapping, including in patients with lesions in the right hemisphere [11]. Looking forward, there are many exciting questions to be pursued using action naming in an intraoperative context, and the clinical preparation afforded by awake language mapping holds tremendous potential to disclose new insights about the neural basis of nouns and verbs. Acknowledgments We thank Drs. Barbara Zarino, Djaina Satoer, Gabriele Miceli, Marla Hamberger, Costanza Papagno, and Effrosyni Ntemou for answering questions regarding specific action naming paradigms and for clarifications of their studies. We thank Ann-Katrin Ohlerth and Effrosyni Ntemou for providing the image used in Fig. 11.2. We are grateful to Drs. Emmanuel Mandonnet, Guillaume Herbet, and Webster Pilcher for comments on an earlier draft, and to Dr. Srdjan Popov for clarifying some aspects of linguistic theory. Preparation of this article was supported, in part, by NIH grants R01NS089069 and R01EY028535 to BZM.
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Verbal Short-Term Memory
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Costanza Papagno and Juan Martino
12.1 Introduction Short-term memory (STM) is the capacity to keep a small amount of information in mind in an active, readily available state for a brief period of time (several seconds to minutes), in the absence of sensory input [1]. STM should be distinguished from working memory [2], which adds processes that support manipulation of the information, providing a basis for goal-directed behaviors [3–5]. Therefore, the difference between STM and working memory is in terms of operativity. In other words, the concept of working memory includes the manipulation of information. Working memory consists of two so-called slave systems, the phonological loop and the visuo-spatial sketchpad, which are coordinated by a control system, the central executive. More recently, Baddeley [6] has added a fourth component, the episodic buffer, that holds multidimensional stimuli from semantic and episodic long-term memory in addition to information from the other subsystems of working memory, combining them into multidimensional episodes (see also [7]). Deficits in working memory are so frequently associated with executive function disorders that some neuropsychologists classify working memory with executive functions. Imagine you move through an airport to reach the boarding gate, you have to memorize the gate, the departure time, the time in advance by which you have to reach the gate, the time it takes to reach the gate, etc. You have to do several mental calculations to estimate if you have to change terminals, if you have to take a train, if there will be a lot of queue at the luggage control, etc. You weigh alternatives, make decisions, and order your thoughts until you think the plan achieves your C. Papagno (*) Neurocognitive Rehabilitation Center (CeRiN), CIMeC (Center for Mind/Brain Sciences), University of Trento, Rovereto, Italy e-mail: [email protected], [email protected] J. Martino Department of Neurosurgery, Hospital Universitario Marques de Valdecilla, Santander, Spain © Springer Nature Switzerland AG 2021 E. Mandonnet, G. Herbet (eds.), Intraoperative Mapping of Cognitive Networks, https://doi.org/10.1007/978-3-030-75071-8_12
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objectives. Working memory stores information in an online fashion, allowing its contents to be easily accessed by other cognitive processes. Consequently, working memory is considered to be one of the most crucial components in the execution of many complex cognitive tasks that require holding and manipulating information for short periods of time, such as general fluid intelligence, reasoning ability, language, learning, mathematical ability, and spatial ability [8, 9, 10–13]. Verbal STM includes the activity of interrelated components. The most popular psychological model of verbal STM distinguishes a component devoted to the storage of verbal information (phonological short-term store—STS—or buffer), and a process (articulatory rehearsal), which revives the memory trace held in the phonological store, preventing its decay. The rehearsal process recirculates verbal information between the phonological STS and a component, the phonological output buffer, or assembly system, participating in speech production. Auditory-verbal input has direct access, after acoustic analysis, to the phonological store, while a written verbal information undergoes a process of recoding in a phonological form and accesses the phonological store by means of rehearsal (see [14]). The main problem with this topic is that different authors not always use in a correct way the term and consequently they test differently (and not always properly) this faculty. Moreover, they use interchangeably working memory and STM, which are in fact two different concepts. Finally, verbal STM includes two distinct information: one concerning the item and the other the order, namely the position of an item in the sequence (see [15]). All tests of simple recognition involve only the item information and not the order one; consequently, they only partially test STM. For the sake of clarity, we will discuss issues concerning verbal STM, which corresponds to the phonological loop of the Baddeley and Hitch’s [2] working memory model. There are indeed other models that are not the focus of this chapter (see [16] for a review). We will also briefly mention some studies on working memory, both verbal and spatial.
12.2 The Neural Basis of Verbal STM Distinct anatomical correlates subserve the different components of verbal STM, as demonstrated by various studies using different methodologies. Indeed, this evidence derives from anatomo-clinical studies in brain-damaged patients (see [17], for reviews), neuroimaging studies with positron emission tomography ([18, 19]; but see [20]) and fMRI [21], and, finally, studies using repetitive transcranial magnetic stimulation [22, 23]. Such different methodologies converge in showing that the phonological short-term store depends on the activity of the inferior parietal lobule (more specifically, the supramarginal gyrus, Brodmann’s area BA 40, but also the angular gyrus, BA 39, see [24–26]), while the rehearsal process depends on the activity of the inferior frontal operculum (BA 44 and BA 6, but also BA 45). Further evidence is provided by direct electrical stimulation studies [27]. Recently, in a voxel-based lesion-symptom mapping study on 103 patients after glioma
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removal [28], the role of the supramarginal gyrus in phonological storage has been confirmed. Verbal STM has been demonstrated to be involved in learning a new language [29] and in sentence comprehension, in particular when word order is crucial for comprehension (like “put the small red square over the big black circle”) or when the sentence is syntactically complex and loads on memory (like “the cat, that the boy is watching, is drinking milk”) (see [16] for a review). In addition, being a component of working memory, its damage impairs functions related to it. Therefore, it is crucial to preserve the phonological loop function during surgery in these areas of the brain.
12.3 L ong-Term Deficits in Patients Who Did Not Benefit from Intraoperative Monitoring of Verbal STM As already mentioned, a serious problem in the memory domain is that clinicians do not use the correct terms in defining the different memory subsystems. In fact, they often name STM what is episodic learning, namely anterograde amnesia. So, they define as STM impairment, the problems reported by patients with anterograde memory/learning deficits. This is particularly evident in the neurosurgical literature. Intraoperative electrical stimulation mapping is an indispensable tool to guide the resection of gliomas within eloquent areas, as it enables to identify and preserve the functional margins, and maximize the tumoral resection [30, 31]. Regarding language mapping, object naming has been the preferred task for identifying cortical and subcortical eloquent sites [32]. The object naming areas identified with this technique are considered essential, as language decline has been observed after removal of these sites [33]. On the other hand, memory areas are generally not considered as part of the “eloquent” brain in neurosurgical practice, and they are currently not localized during brain mapping. However, several glioma series with intraoperative evaluation of picture naming task demonstrated high rates (up to 73.3% in the long term) of postoperative memory impairment, raising the question regarding the efficacy of this approach to preserve memory function [34–39]. Moreover, memory deficits seem to represent one of the main sources of dysfunction in glioma patients affecting their quality of life [40, 41]. Racine et al. [37] evaluated the postoperative neurocognitive function in a cohort of 22 newly diagnosed low-grade gliomas. All patients were operated awake with IES mapping, and evaluation of language with a picture naming task. Memory was not tested intraoperatively. Six months after surgery, seven patients underwent repeated neuropsychological testing, revealing a decline in what the authors call STM tests in 40–60% of cases. However, the effective decline was observed in immediate story recall (which assesses episodic buffer integrity) and backward digit span (assessing verbal working memory) but forward digit span did not decrease. Similarly, the effect of surgery in specific tumor locations like the insula has also been analyzed. Wu et al. [39] studied 35 patients with insular low-grade and anaplastic gliomas operated awake with language IES. The authors report that 3 months
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after surgery, the rate of STM decline was higher than 50%. However, the impaired test was a learning one, as well as a delayed recall test, while verbal STM, as assessed by means of a span task, was not impaired. Teixidor et al. [38] evaluated 23 low-grade gliomas operated with the same methodology of language mapping. Immediately after surgery, 96% of patients showed verbal working memory worsening. Only nine patients had long-term follow-up, but all of them recovered 3 months after surgery with intensive rehabilitation. Martino et al. [36] studied the long-term deficits in a series of 16 patients operated with intraoperative evaluation of language. They reported at 6 months after surgery a 73.3% of STM decline, which was tested with a recognition task and not with serial recall, therefore assessing only item information. In contrast, a single case has been reported [42] who underwent awake surgery for removal of an oligodendroglioma involving Broca’s area and the insula. This patient showed a severe decrease in her auditory-verbal span due to a deficit in rehearsal, coupled with a sentence comprehension deficit. This patient represents a “true” case of STM impairment demonstrated by appropriate testing.
12.4 Locations at Risk of Long-Term Deficits in Verbal STM The identification of specific anatomical hotspots that are critical for adequate STM functioning would be crucial for surgeons. Indeed, it allows knowing which specific brain regions are to be considered “eloquent” for memory. Previous studies demonstrated that intraoperative damage to memory areas is associated with a long-term decline in memory function. Ojemman et al. [43] evaluated language and verbal memory organization by electrical stimulation mapping in 14 adults undergoing left temporal lobectomy for epilepsy. Memory sites were identified at the lateral temporal cortex in 13 cases. At the temporo- parietal cortex, language sites were mainly located in the posterior portion of the superior temporal gyrus, while memory sites were located in the middle and anterior portion of the superior and middle temporal gyri, and in the inferior parietal lobule. Therefore, the authors describe a lateral cortical temporal memory system separated, although adjacent to the posterior language areas. The authors also assessed memory deficits 1 month and 1 year after temporal lobectomy with the Wechsler Verbal Memory Scale. They reported a 22% of verbal memory decrease at 1 month, and 11% at 1 year after surgery. Unfortunately, the previous version of this scale (now accurately revised) evaluated different forms of memory and did not provide a pure measure of verbal STM. In order to evaluate the risk of memory impairment if functional areas were damaged, cases were divided into those with resections that were close or even including language or memory areas, and those with resections far from these functional areas. The resection close or within language and memory areas was associated to an 83% risk of verbal memory impairment 1 year after surgery. On the other hand, when resection was far
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from language or memory areas, the risk decreased to 25. Unfortunately, the authors combine language and memory sites in the resection zone, and the exact number of cases in which memory sites were damaged is not reported. Therefore, based on this report, it is not possible to calculate the exact risk of memory decline when memory sites are damaged. In addition, the authors do not exclusively refer to STM. Campanella et al. [35] evaluated memory sequelae in a series of 75 operated low- grade gliomas. Verbal STM was evaluated preoperatively and 4 months after surgery with the Digit Span Forward. A voxel-based lesion-symptom mapping technique was used in order to identify specific hubs which appeared to be particularly susceptible of causing verbal STM disturbances. Regarding the Digit Span Forward Test, two specific hotspots were identified: the conjunction between the left superior and the middle temporal gyri, and the white matter area involving the intersection between the left inferior longitudinal fasciculus, inferior fronto-occipital fasciculus, and posterior arcuate fasciculus. In the neurosurgical literature there are other studies concerning both verbal and spatial working memory and not specifically verbal STM. We will briefly mention these studies on both, verbal and spatial, working memory. Kho et al. [44] described a single case of a patient with a left frontal desmoplastic gangliocytoma and medically intractable epilepsy that was operated awake with IES. Working memory was evaluated intraoperatively with a backward digit span test. IES identified a working memory area at the left dorsolateral prefrontal cortex. The memory site identified was included in the resection as it was part of the epileptogenic region, and was far from language areas. The authors conclude that this area was critically involved in memory, as neuropsychological evaluation 2 years after surgery revealed a selective impairment in working memory tasks. However, an improvement was observed, suggesting that compensatory mechanism took place. This case emphasizes the important role of the dorsolateral prefrontal cortex in working memory. Spatial working memory decline was evaluated in 24 patients with frontal gliomas, who underwent awake surgery, while performing a spatial two-back task; 14 healthy volunteers were also tested [45]. A significant correlation between spatial working memory deficits and injury to the dorsal frontoparietal subcortical white matter pathways, i.e., the first and second portions of the superior longitudinal fasciculus, was found. Nakajima et al. [46] evaluated intraoperatively working memory in two patients with gliomas in the supplementary motor area using a two-back task. In one of the two cases, the authors decided to resect the positive memory site due to the infiltration of the glioma. The patient presented with an impairment of working memory immediately after surgery, but fully recovered 1 month later. This rapid recovery may be explained by an unmasking of an extensive neurological network involved in working memory.
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12.5 How to Monitor STM Intraoperatively Ojemann et al. ([43], see also [33]) in 1985 designed a task to evaluate verbal STM intraoperatively. This task has been recently used by another group [36]. Each verbal memory trial consists in a sequence of four slides (Fig. 12.1). The first and second slides are black-and-white pictures with a common name with the phrase “This is a” above it. The third slide consists in a 4–8 word sentence that is read. The fourth slide, shown for 4 s, has a black-and-white picture with the word “recall” on it. The patient has to recall if this picture was present or not at the first or second slides with a response type Yes/No. As reported above, this task investigates only the item component of STM, but not the position one, which is also a crucial aspect and can be selectively impaired (see [27]). Each cortical area was stimulated under each test condition. Language sites with interference in object naming or reading tasks were excluded from the memory analysis in order to ensure that the information committed to memory had been processed correctly. A positive verbal memory site was defined with a patient’s inability to recall the pictures during 2 out of 3 of the stimulation trials [47]. One of the main advantages of this task is that, in addition to verbal memory, it evaluates the most important aspects of language with the picture naming and reading tests. The specific aspects of how the tasks are performed intraoperatively are described in Fig. 12.2. Brandlin-Bennet et al. [48] reported the case of a patient with a tumor in the posterior third ventricle undergoing awake surgery to test memory during fornix manipulation. They used a similar task to the previous one. In this case, the distractor task between picture naming and recall consisted in three simple mathematical addition and subtraction problems. However, it is not clear whether the fornix is involved in short-term or long-term memory network. A complete evaluation of verbal STM requires the use of digit span. Papagno et al. [27] evaluated STM intraoperatively by means of this task, which provides both an item and an order information, in a series of 29 patients. Participants heard
Fig. 12.1 Verbal STM task. Each verbal memory trial consists in a sequence of four slides (this figure). The first and second slides are black-and-white pictures representing animate and inanimate items with the phrase “This is a” written above. The third slide consists in a 4–8 words sentence that has to be read. The fourth slide, shown for 4 s, has a black-and-white picture, with the word “recall” written above it. The patient has to recall if this picture was present or not on the first or second slides, and a binary response (Yes/No) is expected
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Fig. 12.2 Verbal STM task. Three different cortical sites are tested with the verbal STM task. In the first and second trains of stimulation, each site is only stimulated during the picture naming part of the task. Therefore, in this stage, picture naming and memory are evaluated. If the stimulation of a specific site induces picture naming errors, then this area is classified as a languagenaming area. If the stimulation of a specific site induces memory errors without picture naming errors, then it is classified as a verbal memory area. In the third train of stimulation, each site is only stimulated during the reading part of the task. Therefore, in this stage, reading and (encoding) memory are evaluated. If the stimulation of a specific site induces reading errors, then this area is classified as a language-reading area. If the stimulation of a specific site induces memory errors without reading errors, then it is classified as a (retrieval) verbal memory area
a sequence of digits and were asked to repeat the sequence in the same order. Stimulation of Broca’s area induced more item errors than order errors, indicating that this area is crucial in maintaining item information. On the other hand, stimulation of the supramarginal gyrus induced significantly more order than item errors, indicating its role in serial order information storage (see Fig. 12.3). Similarly, stimulation of the anterior segment of the arcuate fascicle produced more order than item errors, suggesting that it is involved in transferring order information from Geschwind’s area to Broca’s area. In contrast, two studies evaluated verbal working memory during awake surgery, one by using a verbal N-back task and the other a backward letter span. In the former [46], an occupational therapist read Kana (Japanese syllabogram) at a speed of
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Fig. 12.3 Positive sites during intraoperative brain mapping using digit span. The yellow dots indicate sites where stimulation produced an order error, while blue dots indicate site where item errors were produced. In green sites where both errors appeared. The example show the digit span presented by the examiner (79564) and the two uncorrect responses (left parietal inferior lobule: 79654, order error; Broca’s area: 79364, item error) (modified from [27])
1 sound per second. The patient then repeated the Kana which had been heard 2 sounds before. If the patient provided an incorrect response during stimulation, then a positive mapping site was defined. The backward letter span test was applied by Kho et al. [44] to evaluate working memory in an awake surgery. The stimulation of the dorsolateral prefrontal cortex interfered with this task. There are a number of limiting factors to consider in conducting intraoperative memory testing. Working memory tasks are cognitively demanding; therefore, they may be interfered by multiple factors such as low attention or concentration, pain, discomfort, and recovery from anesthesia. There is a limited time to conduct the testing as the patient quickly becomes tired during intraoperative cognitive testing. Careful attention and a close interaction between the neuropsychologist and the surgeon is necessary in order to distinguish between random errors and significant, repeatable errors.
12.6 F unctional Improvement in Series of Patients Operated on with Versus Without Verbal STM Monitoring Short-term and working memory areas are not considered by most neurosurgeons as part of the “eloquent” brain and are thus not localized by intraoperative electrical stimulation. The series evaluating long-term deficits when memory areas have been identified and preserved are scarce.
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Martino et al. [36] in a matched paired cohort study compared the memory decline in a cohort of 16 subjects with gliomas that were operated with intraoperative evaluation of language and verbal memory (cohort A), with a cohort of 16 subjects that were operated with intraoperative evaluation of language (cohort B). Verbal memory was evaluated intraoperatively with a picture naming-reading-memory task that has been previously described. Detailed neuropsychological assessment was performed before and 6 months after surgery. Intraoperative memory mapping was a strong predictor of verbal memory prognosis. Memory decline was significatively reduced from 73.3 to 26.7% by adapting the resection to avoid those memory areas. In a VLSM study performed on 103 patients undergoing resection in general without STM monitoring [28], postoperative digit span scores were linked to lesions in both the left supramarginal gyrus and superior-posterior temporal areas, as reported in the literature on patients with a selective deficit of auditory-verbal STM.
12.7 A dditional Anatomo-Functional Knowledge Gained from Intraoperative Mapping Studies The use of STM tasks in intraoperative mapping studies has produced relevant information on current models of STM and it has prompted new research. For example, a more detailed mapping of the phonological loop has been provided, including pathways connecting the different buffers (see Fig. 12.4). In addition, since a specific site for order information was found during awake surgery [27], Guidali et al. [15] conducted a series of TMS experiments, in which participants
Fig. 12.4 The anatomical correlates of verbal STM. Cortical areas and subcortical pathways. ARCd direct segment of the arcuate fasciculus (in red), ARCp posterior branch of the arcuate fasciculus (in yellow), SLF-III third branch of the superior longitudinal fasciculus, or anterior branch of the arcuate fasciculus (in green) (from [28], Brain Structure and Function)
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performed different STM tasks, requiring maintenance of an ordered sequence in three distinct modalities (verbal, spatial, motor), and they demonstrated that the left supramarginal gyrus is one key node of the STM network involved in retaining an abstract representation of serial order information, independently from the content information, namely the nature of the item to be remembered, which instead is stored separately. This is very relevant from the point of view of rehabilitation, since many human tasks require serial order as Lashley pointed out in 1951 [49]: “Temporal integration is not found exclusively in language; …the architect designing a house, and the carpenter sawing a board present a problem of sequences of action.” Sequencing would depend from a single structure.
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Proper Names Retrieval
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Costanza Papagno and Carlo Giussani
13.1 Introduction Naming familiar people has a fundamental role in human social life [1]. It is a more demanding task than naming objects [2], and, therefore, more vulnerable when cognitive resources are globally reduced. Indeed, proper name retrieval is one of the most common difficulties in the aging population [3]. It is reported that 30% of people above age 65 complain of difficulties in word retrieval, and among them, 64% have problems in retrieval of proper names. Accordingly, James [4] found that older adults show greater impairment in learning proper names than other biographical information in association with a new face, possibly because proper names establish a single, direct link with one correct exemplar [2]. Unlike common names, exemplars with the same proper name do not in general share the same characteristics (not all people named “Sharon” have the same hair color). Proper nouns are considered pure referring expressions [5] without sense, defining individual entities, while common nouns refer to anyone of a class of beings or things. However, the deficit in proper name retrieval cannot be explained with the above reported fact that proper nouns are more difficult to retrieve than common ones. In fact, there are cases of double dissociations suggesting that proper name retrieval engages different functional processes with respect to common nouns. Indeed, neurological damage can result in a proper name deficit, while common names are unaffected, and the opposite condition, namely sparing of proper nouns with anomia for common nouns, has also been observed, although less frequently C. Papagno (*) Neurocognitive Rehabilitation Center (CeRiN), CIMeC (Center for Mind/Brain Sciences), University of Trento, Rovereto, Italy e-mail: [email protected], [email protected] C. Giussani School of Medicine and Surgery, San Gerardo Hospital, Monza, Italy e-mail: [email protected] © Springer Nature Switzerland AG 2021 E. Mandonnet, G. Herbet (eds.), Intraoperative Mapping of Cognitive Networks, https://doi.org/10.1007/978-3-030-75071-8_13
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[6]. Other examples are preservation of people’s names despite severe jargon [7], and preservation of the ability to write famous people’s and geographical names [8] despite impaired ability to write common names. Semenza [2] suggested that at least four different varieties of proper name anomia exist, namely (1) pure proper name anomia, in which the deficit is at a post-semantic level, consisting in a failure to access the name’s phonological form from an intact semantic system; (2) anomia from damage at the semantic level, in which the information about people is selectively lost; (3) isolation of individual semantics, in which the information is available but only when the patient is given the proper name itself; (4) prosopanomia, i.e., anomia for faces, in which the patient is unable to retrieve the name from face but can do it on definition. In all these cases, the processing of common names is virtually intact. This reported distinction is drawn referring to an information processing model [9], which considers the input from different sources, i.e., names, definitions, faces, and voices, activating individual semantics, while names, definitions, and visual images of objects activating general semantics. In other words, the name George Clooney, his voice, or the definition “a North American handsome actor playing the role of a pediatrician in a famous TV series” activate semantics of a specific individual, while the word “dog” or the barking of a dog or the definition of an animal with four legs that barks activate a general semantic which is not specific for a single dog. Both individual and general semantics, in turn, independently activate the phonological forms in the lexicon. The activating mechanisms are thus separate. More frequently, the proper name impairment is a post-semantic deficit (see [2] for a review). Accordingly, patients are in general able to retrieve biographical information about people they could not name, suggesting normal recognition of them.
13.2 The Neural Basis of Proper Name Retrieval Converging evidence from semantic dementia, lesion and functional imaging studies have shown that the most anterior portion of the temporal lobe (ATL), namely BA 38 and possibly the adjacent enthorinal cortex, is certainly involved in the retrieval of proper names. Indeed, its damage is associated to it, leaving intact the access to names of entities at categorical level, i.e., common nouns (see, for example, [10–13]). This area is also crucial for learning new proper name-person relationships [14]. In addition, the ventral anterior portion of the thalamus may be involved in the retrieval of names by activating and coordinating the left temporal lobe (where proper names may be stored) and the left frontal language area, which is crucial to the production of any verbal output [15, 16]. According to Damasio and Tranel [17], the ATLs are converging or intermediating [10] zones for the different components of a distributed representation of people in order to retrieve a name [10]. However, Semenza [18] highlighted that the left temporal pole only provides some resources to the naming process and its involvement is not mandatory. Cases of near global proper-name anomia have occurred in patients with left parieto-occipital [19–22] and left fronto-temporal lesions [23], suggesting that both
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anterior and posterior cortical regions are engaged in proper name retrieval. The mechanism underlying proper names impairment in these posterior lesions is not clear. In fact, in a 4% of patients with lesion in the left ATL there is a normal proper name retrieval, while an abnormal performance has been found in 12% of subjects with lesions outside the ATL. For example, Otsuka et al. [24] described a patient with a proper name retrieval deficit, showing a rostro-caudal elongated high intensity area in the subcortical region along the upper bank of the superior temporal sulcus, sparing Heschl’s gyrus and adjacent parts of Wernicke’s area, but including the caudal ¾ of the STG, SMG, MTG, and parts of the optic radiation, tapetum, and inferior longitudinal fasciculus. Additional small bilateral, frontal parietal, temporal lesions in the deep white matter were found. The anterior part of the temporal lobe, the uncus, and hippocampus were not affected. People’s name anomia has been also caused by lesions in the left basal ganglia (amygdala included) [19, 25, 26], as reported by Yasuda et al. [27]. The deficit in retrieving proper names can extend to other unique entities, such as famous places [28, 29]. This deficit seems modality-aspecific, involving name retrieval on visual and auditory stimuli, as well as on verbal description [30]. A further structure that seems to be involved in proper name retrieval is the uncinate fasciculus (UF). In a study on 44 patients submitted to awake surgery for removal of a left frontal or temporal glioma, Papagno et al. [31] found that 18 patients, in whom the removal included the UF, showed a significant impairment in naming of famous faces as compared to patients without removal. The percentage of patients without UF removal but long-lasting deficits was negligible. Crucially, the two groups did not differ before surgery. When patients were further divided according to the site of the tumor (either frontal or temporal), those with a temporal glioma who underwent UF removal had the worst performance in famous face naming at 3 months after surgery. In addition, on the same task, the group with a frontal glioma that underwent resection of the frontal part of the UF performed significantly worse than the group with a frontal glioma but without UF removal. In conclusion, the resection of the UF, in its frontal or temporal segment, produces long-lasting consequences for famous face naming. Therefore, this fiber tract seems to be part of a circuitry involved in the retrieval of word form for proper names. Retrieval of conceptual knowledge was intact. In a subsequent follow-up study of 17 patients at 9–12 months who did not suffer any tumor recurrence, Papagno et al. [32] showed that proper naming remained significantly impaired with no improvement after 12 months in patients with UF removal. However, naming was not always affected following UF resection. Normal performance in naming persons despite temporal lobe lesions was found by Damasio et al. [33]; Semenza [9] concluded that a dedicated module dealing with proper name retrieval is either distributed in a large portion of the left hemisphere or subject to great interindividual variation. Therefore, one cannot predict that nearly equal lesions (and of course lesions cannot be absolutely identical) would be associated with precisely the same deficits. Naming unique faces also requires regions related to the processing of emotions, such as the ventromedial prefrontal cortices [33], the UF being also a crucial structure in emotion.
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Age of lesion is another important variable. Indeed, anterior temporal lobectomy to manage pharmaco-resistant temporal lobe epilepsy produced no postsurgical impairment in proper name retrieval in patients with an early onset of seizures that probably produced a reorganization outside the left ATL [34]. Neuroimaging studies confirmed this role of the left ATL [10]. In conclusion, we suggest that the left anterior temporal regions contain zones acting as intermediaries between retrieval of conceptual knowledge and retrieval of names. Therefore, at least three types of neural structures would be involved in the network for naming people, namely those supporting conceptual knowledge, those supporting the implementation of word forms in eventual vocalization, and the intermediate ones, which are engaged by the structures supporting conceptual knowledge to trigger and guide the implementation of a word form [35]. The UF could connect the intermediary structures to those involved in the retrieval of word form for proper names.
13.3 L ong-Term Deficits in Patients Who Did Not Benefit from Intraoperative Monitoring of Proper Name Retrieval Unfortunately, the follow-up of neurosurgical patients is difficult to relate directly to the intervention. Many of them undergo radiotherapy or chemotherapy, which introduce possible side effects on cognition [36]. In several cases tumors show an aggressive behavior and progress quickly affecting the neuropsychological performance of patients [37], and some patients can die during the follow-up period. Patients may suffer tumor recurrence, requiring repeated surgical procedures [38] that can cause further deficits or worsen previous ones. In this view, stable findings at follow-up can be sought after surgery for epilepsy. In this situation, resection of ATL has been associated with proper name retrieval deficit especially when the resection is performed on the dominant side. Such finding has been commonly experienced by several epilepsy surgeons and some strategies have been put in place in order to elude the risk of a permanent deficit. In a report by Kendall and colleagues, a presurgical training for famous faces, famous places, and personally relevant faces was able to increase the maintenance of those skills after surgery or to increase the performances after surgery [39]. These results suggest that circuits involved in name retrieval have some plasticity and it is possible to speculate that this feature might be related with the fact that multiple brain regions (cortical and subcortical) are involved in object and proper name retrieval. This fact justifies how complex is to define both the function of name retrieval and the location of this function in a circumscribed area of the brain. In addition, proper name retrieval is not considered a first-choice function to be preserved by neurosurgeons. Consequently, there is little concern about the presence of this deficit and it is not often monitored intraoperatively or checked in follow-up studies.
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In the previous paragraph we have reported the follow-up at 1-year of a group of patients who continued to show deficits in proper naming [32], suggesting that left ATL and UF removal produces a permanent deficit of this ability. Similarly, a patient was described with a severe deficit in retrieving proper names after a left anterior temporal lobectomy [40]. He was unable to retrieve proper names in conversation or when shown photographs or given verbal descriptions of people, despite being able to provide semantic information about the person he could not name. Comprehension of names was preserved, since he could point to his relatives’ photographs and famous people’s pictures when the name was produced by the examiner. His ability to retrieve common nouns was relatively intact. A more recent study [41] reported that patients with language-dominant temporal lobectomy were impaired in retrieval of familiar and newly learned people’s names, while in nondominant lobectomy the difficulty only concerned newly learned people’s names. Finally, Moran et al. [42] described a deficit in acquiring face and person identity information following anterior temporal lobectomy.
13.4 L ocations at Risk of Long-Term Deficits in Proper Name Retrieval Observations from neurodegenerative diseases and surgery represent the most important evidence about long-term deficits in proper name retrieval. As depicted above, name retrieval represents a complex brain function performed by the interaction of more than one cerebral structure. In particular, proper name retrieval seems to have the main core structure in the ATL. Around this part of the brain, connections with the surrounding structures like fusiform gyrus, amygdala, thalamus, frontal cortex, etc. contribute to realize proper name retrieval. As a consequence, lesions of one of such areas can produce a deficit in this function which might be disabling [43]. Given the extended network behind proper name retrieval, it has always been difficult to establish and map a specific and circumscribed area of the brain devoted to this function. However, all the reported evidence suggests that face naming can be mostly impaired in case of dominant temporal pole removal, with a permanent deficit when subcortical fibers are included; but, in some cases, it can appear also after nondominant temporal pole resection, eventually secondary to impaired face recognition. Studies from neuro-oncological patients have contributed to the description of neuropsychological brain functions as a consequence of a lesional surgery but, on the other hand, surgery usually interferes with a pre-existing neoplastic brain damage. Moreover, patients can be very heterogeneous with different brain areas simultaneously affected by the same tumor. So far, studies on these patients might deliver indirect or incorrect information about the neuropsychological functions of the brain. Studies from brain mapping performed during surgical removal of brain tumors allowed to recognize a brain area more extended than the temporal pole that encompasses the lateral aspect of the frontal lobe (superior, middle, and inferior
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frontal gyri) and the anterior part of the superior and middle temporal gyri [44]. Such areas showed that there is also an overlapping between famous face naming and object naming which renders the study of name retrieval quite challenging. In the study by Giussani et al., most interferences (50%) were typical face anomia with patients able to recognize the face or to evoke related biographic information but without being able to name the corresponding person. Interestingly, semantic paraphasias (patients attributing repeatedly a wrong name to a famous face) were found mainly in the frontal gyri and the superior temporal gyrus [44]. This result is in line with a tDCS study [45] in which anodal tDCS over the left ATL decreased naming accuracy compared to sham stimulation because participants produced significantly more intrusions. Apparently, stimulation increased interference among arising competitors when retrieving the correct name associated to the presented face. Anodal tDCS over the left IFG led to a significant decrease in intrusions compared to sham stimulation, possibly improving the selection mechanism. Although knowledge of the cortex and its functions has increased over time, that of white matter connections and their functions is still a matter of study and debate. Indeed, face naming can be affected also by resection of white matter tracts despite sparing the ATL. This fact has been enlightened in the study by Papagno et al. [31], as reported above.
13.5 How to Monitor Proper Name Retrieval Intraoperatively Brain mapping procedure consists of a general assessment of naming, namely an object naming (animate and inanimate objects) and an action-naming task because it is easily reproducible and effective in searching for standard anomia. A famous face naming should be added, especially when surgery concerns tumors involving the left ATL. Before concluding the direct brain mapping procedure, essential naming sites are routinely confirmed by repeating the naming task. Findings on different tasks may be affected or biased by the frequency or familiarity of the items presented. The object-naming task and the famous face-naming task are not equivalent in terms of lexical frequency and complexity. This lack of comparability could be explained by the differences existing between these two categories, as reported above. The face-naming stimuli are colored or black-and-white photographs of celebrities taken from different categories of public life (actors, politicians, sportsmen/women, etc.) balanced for gender, when possible by nationality (half from the patient’s same country and half foreigner people), alive or dead. Faces are presented in a prototypical pose and appearance. A correct response is defined as the complete and exact famous person name or only the surname when this unequivocally defines the celebrity. Ability in naming people is variable also in healthy individuals. Therefore, the best procedure to adopt is to evaluate face naming before surgery, during the baseline assessment. For intraoperative testing, only items produced correctly three times out of three without delay should be selected for intraoperative monitoring. Therefore, each patient is submitted to a specific, ad hoc intraoperative protocol
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designed according to his/her presurgical performance; also, each patient serves as a control for him/herself. Items are presented by means of a computer screen and 3 s are allowed for response. A different way to assess proper name retrieval could be through voice, thus confirming that the problem is not one of face recognition, but typically a naming one. A short fragment not containing any element that could allow the direct recognition of the person (neutral discourses) can be presented to the patient who has to name the person’s voice. This task has been submitted to 15 patients with a left temporal lobectomy and 13 patients with a right lobectomy and only left patients were impaired in naming [46]. Although cortical and subcortical mapping during brain tumor resection are becoming common practice in neurosurgery, some limitations in awake surgery have been enlightened through the years. First of all, awake surgery requires the patient’s collaboration which needs to be optimal under conditions of high stress. This means that some of the results might be altered because of lack of compliance by the patient. Second, as reported in 2019 by Roux et al., in order to have a sure and reliable finding at least three trials are needed. So far, the need of more than one positive confirmation might increase the stress on the patient and the reliability about its collaboration [47]. This is particularly relevant considering that face naming in general is performed after object and, eventually, action naming. Finally, the patient’s pathology might influence the results of testing. In fact, patients undergoing surgical resection for epilepsy are different from patients undergoing tumor resection. Patients with drug-resistant epilepsy might have altered brain networks due to long-standing epilepsy while patients with brain tumors might have altered cerebral networks due to white matter dislocation or infiltration or due to perilesional edema. Among these patients, those with high-grade gliomas (HGGs) and those with low-grade gliomas (LGGs) can present several differences: patients with HGGs might be impaired in face naming due to associated edema or mass effect while patients with LGGs might be impaired because of white matter infiltration. These two different patterns of impairment definitely affect the surgical outcome in terms of safe resection on functional structures like the cortex or white matter bundles. In case of HGGs, white matter bundles might be spared due to the displacing behavior of the tumor during its growing; in the case of LGGs, white matter bundles are not spared by the tumor due to its infiltrative nature. As a consequence, resection of HGGs might interfere with object and face naming mainly due to a cortical damage, while resection of LGGs can affect them because of a cortical and subcortical damage. In the same way, cortical and subcortical mapping might be influenced by the behavior of the tumor [48]. A further limitation is that the possibility exists that the patient cannot retrieve the name because he/she does not recognize the face. In other words, a problem of recognition cannot be excluded. However, in general they spontaneously report semantic information (see above, as reported in Giussani et al.’s paper), suggesting that recognition is unimpaired; in addition, there is an increasing literature confirming that face recognition depends on the nondominant hemisphere, while naming is related to the dominant one (see [49, 50] for reviews, [51]). Additionally, the same
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problem, namely a lack of recognition, would concern object naming. Finally, a voice-naming task, as reported above, can help in the diagnosis. A similar procedure has been used by Kurimoto et al. [52]. The picture-naming task for famous people’s faces was undertaken, after object naming, on the exposed areas of the superior and middle temporal gyri but no positive sites were found. However, postoperatively, their patient showed marked difficulty in retrieving famous people’s names that extended to his friends and coworkers making impossible for him to return to work; the deficit remained stable for 15 months, despite speech therapy. The authors suggest that the crucial aspect, apart from the resection of the anterior temporal lobe and temporal base (areas 20, 28, and 36), was the removal of subcortical pathways. Accordingly, stimulation of a subcortical area, underlying the temporal pole and probably corresponding to the UF (although DTI was not available), produced proper name anomia (see Fig. 13.1 and [44]).
Fig. 13.1 Subcortical intraoperative mapping of famous faces, showing a dissociation between proper (Joseph Ratzinger) and common (bed) nouns in the left temporal lobe. Site (12) is a cortical area involved in naming things, while (31) corresponds to a subcortical site whose stimulation produces disruption of proper names. The schematic drawing of the temporal lobe depicts the position of the two sites. Note that the black dot reported on the cortex corresponds to the underlying white matter (Modified from [44]).
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13.6 F unctional Improvement in Series of Patients Operated with Versus Without Proper Name Retrieval Monitoring Monitoring patients for proper name retrieval is not easy, because of the multiple areas involved in this function, but it should be considered each time the temporal pole is involved. In any case, the intraoperative mapping of proper names is limited to a few cases. Surgeons try to preserve language in general, without considering such specific aspect of language. In fact, extension of resection is considered a critical prognostic factor for delaying the progression and increasing survival. Considering the proved benefit of a radical surgical approach, a major criterion in selecting the surgical strategy should be the preservation of the neurocognitive profile and, as a consequence, the quality of life. Therefore, extension of resection is considered the priority, and proper name is “sacrificed,” since it is not considered a crucial ability, as already reported. Although in the literature few preliminary experiences about the potential long- term compensatory mechanisms that patients can train in order to overcome the acquired name retrieval deficit are reported, present experience shows that such a deficit in proper naming is permanent and not solved by speech therapy, especially when the subcortical pathways have been resected [32, 52]. Deficit in proper names retrieval might preclude return to work. This aspect should be carefully considered at least in those cases in which ability with proper names is a fundamental function for the professional life of that specific patient.
13.7 A dditional Anatomo-Functional Knowledge Has Been Gained from Intraoperative Mapping Studies As repeatedly reported in this chapter, intraoperative mapping on proper names, though performed very seldom, has produced important outcomes from an anatomical point of view. It has confirmed that proper name retrieval is based on a complex network involving several structures in the brain, the core one being the left ATL; it has also shown that white matter pathways are crucial in producing permanent deficits, and a fundamental bundle of fibers is represented by the UF. Therefore, researchers have pointed their attention on this structure and an increasing number of investigations has focused on the property of the UF. Finally, an important information that has been acquired is that despite the complex circuit involved in proper name retrieval, some of its components are unique, so that, despite the potential plasticity that has been described in brain tumors, especially in LGGs, no recovery seems possible in the case of damage of subcortical fibers. An example is represented by four patients in Giussani et al.’s [44] series who, when tested preoperatively, had a partially selective famous and relative’s face anomia. All of them had tumors in the anterior part, cortical and subcortical, of the left temporal lobe, so that face-naming mapping was impossible.
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Alejandro Fernandez-Coello, Santiago Gil-Robles, and Manuel Carreiras
14.1 Introduction: Neural Basis of Bilingualism The neural bases of language processing in bilinguals have been extensively investigated with the advent of neuroimaging techniques, such as the functional magnetic resonance imaging (fMRI) and the electrical stimulation mapping (ESM). However, there are still many unanswered questions and live debates on (1) which cortical and subcortical areas of the language circuit show common and specific activation for the two languages; (2) to which extent overlap in the language circuit depends on the age of acquisition, proficiency, or language exposure; (3) which language control mechanism allows to manage two languages in one brain so that we can speak only in one language at a time while avoiding intrusions from the other language; and (4) the brain plasticity associated to tumor growth and tumor resection in a bilingual brain.
A. Fernandez-Coello Hospital Universitari de Bellvitge (HUB), Neurosurgery Section, Campus Bellvitge, University of Barcelona e IDIBELL, L’Hospitalet de Llobregat, Barcelona, Spain CIBER de Bioingeniería, Biomateriales y Nanomedicina (CIBER-BBN), Barcelona, Spain University of Barcelona, Barcelona, Spain e-mail: [email protected], [email protected] S. Gil-Robles Department of Neurosurgery, Hospital Quiron, Madrid, Spain BioCruces Research Institute, Bilbao, Spain M. Carreiras (*) BCBL, Basque Center on Cognition, Brain and Language, Donostia-San Sebastián, Spain Ikerbasque, Basque Foundation for Science, Bilbao, Spain University of the Basque Country, UPV/EHU, Bilbao, Spain e-mail: [email protected] © Springer Nature Switzerland AG 2021 E. Mandonnet, G. Herbet (eds.), Intraoperative Mapping of Cognitive Networks, https://doi.org/10.1007/978-3-030-75071-8_14
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ESM studies on bilinguals [1–4] have shown the co-existence of common brain regions for the two languages through language-specific areas. In particular, they reported disruptions during stimulations in sites where speech arrest arose for both languages and sites where speech arrest arose for one language but not for the other. Thus, language circuits are crafted with common and specific pathways. In addition, studies using ESM have revealed remarkable differences in language areas between individuals, rendering the overlapping range of sites very variable [1, 2, 5]. Ojemann and Whitaker [3] already noticed this variability when reporting, for the first time, different cortical-functional sites (frontal and parietal) in two bilingual patients, using a picture naming task under ESM. More recently, the same team reported frequent but variable overlap in temporoparietal areas for L2 and L1. However, none of the 22 patients had complete overlapping of L1 and L2 and 8 of them had no overlap at all [1]. Similar results have also been reported in bilingual pediatric population using several tasks [6]. Serafini et al. tested bilingual patients with reading and naming tasks; they reported the existence of overlapping “multitask” cortical areas in the frontotemporal regions and single language task sites more located in the postcentral areas. These data align with the previous results supporting the idea of a specific functional network for multilinguals with variable overlapping. Not surprisingly, European and Asian teams using ESM in multilinguals have found results that are also very similar to those summarized in 2007 [2] in a review by Giussani and, more recently, in 2019 by Teo et al. [7] and Roux and Tremoulet [4]. For example, Roux and Tremoulet stimulated cortical areas of 12 right-handed bilingual patients during surgery, using counting and reading, besides naming tasks, and found strict overlapping of both languages in only 5 of them, which implies that differences in the networks subserving each language are general and not task-specific. Similarly, neuroimaging studies have revealed common and specific activation for the two languages in a bilingual brain [8]. In a seminal work using fMRI with bilinguals, Kim et al. [9] reported overlap of activation for L1 and L2 in the left inferior frontal gyrus if both languages were acquired early, but different spots of activation if the L2 was acquired later in life. However, overlap of activation was found in the left superior temporal gyrus both for early and for late bilinguals. Many other teams have reported different networks subserving the organization of multilingual brains, with variable overlapping. In fact, current evidence suggests that languages are represented mostly in overlapping networks, including areas within the left perisylvian cortex and frontal, temporal, and parietal regions as well as subcortical structures. In short, similar activation has been found for the processing of the L1 and L2 in the so-called language network [10–13]. Nonetheless, some studies have also reported language specificity in several brain regions attributed to age of acquisition (AoA) and proficiency differences [14, 15]. Whether the same or different brain areas get activated for each language seems to be modulated by age of acquisition, proficiency, usage, and exposure, among other variables. Though controversial, ESM evidence supports the idea that the languages acquired earlier in life may have a larger cortical representation [16–20]. However, others have found that the number of distinct cortical sites for L2 was
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much higher than for L1, suggesting that the use of L2 implies a wider functional network [21]. On the other hand, regarding similarity between languages, it is noteworthy that a recent fMRI study [22] with native speakers of four very different languages (Chinese, English, Hebrew, and Spanish) showed mostly brain activation overlap for the four languages, together with some specific activations during speech and reading. It is important to note that these four languages differ in many linguistic and orthographic dimensions (e.g., logographic vs. alphabetic Chinese vs. the three others; opaque vs. transparent orthographies: English and Hebrew vs. Spanish.), and the main result is a high overlap of activation for print and speech. The fact that similar neural networks get activated during the processing of two different languages brings up to the table another interesting question: how bilinguals are able to manage the two co-activated languages so that they can speak in one of them without interference from the other. Bilinguals need to focus on the target language while inhibiting the nontarget language or ignoring it. To do so, and to account for the lack of interference between languages, a language control mechanism responsible for language switching has been proposed. This control circuit would be different from the language circuit. In fact, some researchers [23, 24] suggested that cortical areas outside the language circuit such as the right dorsolateral prefrontal cortex, and subcortical areas like the caudate, should be involved in language control. Specifically, the language control mechanism recruits neural regions involved in the control of action in general [25], including the dorsal anterior cingulate cortex (dACC)/pre-supplementary motor (pre-SMA) area, the left prefrontal cortex, the left caudate, and the inferior parietal lobules, bilaterally together with control input from the right prefrontal cortex, the thalamus and the putamen of the basal ganglia, and the cerebellum [24]. Finally, low-grade gliomas may induce plastic changes in the topography of brain functions [26]. In most of the cases, the slow growth of the tumors promotes neural reorganization so that patients are often neurologically normal or only slightly impaired. Eloquent functions can be redistributed in neighbor areas around the tumor, and/or recruited by a distributed network within the lesioned hemisphere and/or in the contralateral hemisphere [26], and this can change also after surgery. Some previous studies on patients with LGGs in eloquent brain areas suggested that post-surgery functional compensation occurred mainly in peritumoral and in contratumoral regions [27–31]. However, Lizarazu et al. (2020) [32], using magnetoencephalography (MEG), found that functional connectivity in peritumoral regions was higher 3 months after surgery than before surgery. In contrast, alpha functional connectivity values in contratumoral areas did not differ between sessions. Interestingly, this enhancement of functional connectivity that emerged in the alpha frequency band was observed in all patients regardless of the LGG location. Thus, post-surgery functional reorganization in peritumoral regions may be a general mechanism of brain plasticity that plays a major role in the recovery of brain function through compensatory mechanisms. Importantly, the preservation of white matter tracts (long-distance connectivity and U-fiber white tracts) may be critical for plasticity in these regions [33]. The risk of inducing permanent deficits without functional recovery is very high in cases of white matter injury [34]. It remains to
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be seen whether the same compensatory mechanisms work for L1 and L2 in bilingual brains.
14.2 I ntraoperative Language Monitoring in Bilingual Patients Comparative data between selective impairment of one specific language in patients operated on and brain mapping and those undergoing brain surgery without are scarce. One possible explanation may be the fact that this specific language and cognitive evaluation in multilinguals, which is needed to monitor these potential sequelae, is only performed in patients undergoing mapping and awake brain surgery, with the precise purpose of reducing this kind of deficit. Multilingual patients undergoing brain surgery without mapping are simply not tested for language in most series. Then, the specific rate of selective language impairment in this last population is widely unknown. Some limited data are available in the literature about long-term impairment of a selective language in multilinguals. One of these cases of selective language impairment has been reported after stroke and left frontal brain tumor by Ibrahim [35, 36] in Arabic-Hebrew bilinguals. The patient showed selective difficulty for the lexical access in one of the languages after lesioning. Others have noticed selective aphasia of one language during the Wada test [37, 38] or after perisylvian surgery of MAV [39]. However, none of these data of selective language deficit in bilinguals who did not benefit from intraoperative monitoring are strong enough to compare with data from the mapped population. In any case, several considerations can be made. To date, ESM has been established as the best way to avoid permanent deficits in brain tumor surgery [2, 18, 40]. Thus, there are no phase-three randomized control trials in the field comparing postoperative deficits after surgery in eloquent areas with and without ESM. Nonetheless, there is a recent meta-analysis of 10 years of published studies comparing the short- and long-term neurological deficits of series of patients having undergone surgery for supratentorial gliomas with and without intraoperative mapping [40]. This meta-analysis showed a rate of permanent deficits in the unmapped population of 8.3% vs. 3.4% in the mapped population, with a median resection volume of 78% in the mapped vs. 58% in the unmapped. This means that the unmapped population has almost three times more risk of developing a long-lasting neurological deficit. The results of this meta-analysis have important implications for the intraoperative mapping in bilinguals. Considering that they have at least the same risk as monolinguals, bilinguals should be mapped. In fact, they could be tested only in one of the languages if the neural circuits underpinning the two languages overlapped. However, the empirical evidence shows that, while there is some overlap, multilinguals seem to have specific networks also not shared for all the languages. Therefore, performing multilingual intraoperative tests is probably the best way to avoid a selective language deficit, testing separately not only all the languages but also the ability to switch between them, as switching is crucial in patients using at least two
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languages in daily life. Not performing these tasks may result in a loss of quality of life [7], as shown for other neurological functions [40].
14.3 Cortical and Subcortical Key Networks for Bilinguals The evidence from research on bilingualism studies using ESM has shown that most of the functional points are within the perisylvian classic language areas (namely the inferior frontal gyrus—pars triangularis, orbitalis, and opercularis—, superior temporal gyrus, supramarginal gyrus, angular gyrus, etc.: IFG, STG, SMG, AG). However, a significant percentage of them are still located outside of the perisylvian areas, recruiting cortical regions not traditionally regarded as subserving language functions, such as the mid-frontal gyrus (MFG). On the other hand, it is well established nowadays that intraoperative testing of language networks implies subcortical stimulation of language-related tracts. Data on subcortical stimulation have helped to define the brain connectivity and build models of language organization [41, 42]. Subcortical tracts were also reported in bilinguals. Using naming and counting tasks together with stimulation of subcortical tracts in seven high proficiency multilingual patients, Bello et al. reported specific subcortical tracts for L1 in four patients and L2 in three patients; however, authors did not specify which tracts were differentially involved [18]. Subcortical connectivity is of critical relevance to investigate the portrayal of two languages, but also to understand the ability of bilinguals to switch between languages. At the cortical level, dominant dorsolateral prefrontal cortex in the middle frontal gyrus seems to be highly specified in this shifting mechanism, as recently demonstrated by Sierpowska and Fernandez Coello [42]. These results align with those reported by Duffau and colleagues during subcortical stimulation of the superior longitudinal fasciculus, which generated intraoperative and post-surgery involuntary language switching in bilinguals. Stimulation of this bundle generated a transitory “disconnection” of the speech areas, which need to be functional in order to avoid switching impairment [43, 44]. Some other studies agree with the left dorsolateral prefrontal region as a fundamental piece in the executive control of language switching (LS). Lubrano et al. reported the participation of the left dorsolateral prefrontal region in LS in a case study in which the ESM caused involuntary LS when this region was stimulated [19]. However, other regions seem to contribute to language control. For instance, Sierpowska et al. [45] identified the posterior middle frontal gyrus as being involved in the process of controlling language because, when it was stimulated, patients showed control language difficulties in LS. In addition, Tomasino et al. [46] describe an involuntary LS after stimulation during a mapping procedure in the superior temporal region. Wang et al. [47] provided new evidence of basal ganglia involvement in LS. Using ESM during the performance of LS tasks, their results showed a participation of the head of the left caudate nucleus. Taking into account the information about cortical and subcortical connectivity, Duffau and collaborators proposed an ESM-based model of LS that involves a large cortical-subcortical neural network. The model would include an executive system
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(prefrontal cortex, anterior cingulum, caudate nucleus), controlling a more dedicated language subcircuit, which involves posterotemporal areas, supramarginal and angular gyri, Broca’s area, and the superior longitudinal fasciculus [48]. To sum up, in the case of bilinguals, it is important to test both languages and language switching not only on cortical sites but also in subcortical units and white matter tracts for cortical and subcortical connectivity.
14.4 N ewly Designed Tasks for Monitoring Multilingualism Intraoperatively Picture naming tasks are currently the gold standard for identifying eloquent areas during awake brain surgery [49–51]. With multilingual populations increasing worldwide, patients frequently need to be tested in more than one language. In addition, a detailed and precise language mapping procedure requires picture naming of objects and actions. Some previous studies using ESM reported a dissociation between temporal and frontal regions when stimulating objects and actions [52–55]. This dissociation between nouns and verbs has been demonstrated at the behavioral, electrophysiological, and brain activation levels (see Chap. 11 and [56]). Therefore, testing object and action naming in the two languages of a bilingual patient with comparable stimuli is desirable for a comprehensive mapping. MULTIMAP [57] is an open-source battery that entails a multilingual picture naming of objects and actions for mapping eloquent areas during awake brain surgery. Pictures included in the MULTIMAP test are colored drawings of objects and actions that have been standardized in nine different languages (Spanish, Basque, Catalan, Italian, French, English, German, Modern Standard Arabic, and Mandarin Chinese), controlling for name agreement, frequency, length, and neighbors across objects and verbs in nine languages and their combinations. Thus, the database was designed for allowing direct comparisons between objects and actions within and across languages (i.e., Spanish-Basque, Spanish-Catalan, Spanish-Italian, Spanish- French, Spanish-English, Spanish-German, Spanish-Modern Standard Arabic, and Spanish-Chinese). MULTIMAP will improve language mapping in multilingual patients, testing objects and actions, and facilitating the identification of areas that show interference in all or only one of their languages that would not be detected by a monolingual test. Moreover, although the use of object naming tasks is widespread across surgical teams in many different geographical locations, heterogeneity in the stimuli selection criteria of pictures across different studies hinders comparison and generalization of results. The MULTIMAP battery allows for direct comparison between objects and actions as well as between pairs of languages in awake surgery. The use of single picture naming tasks to test the different languages is mandatory but it is not fully comprehensive to capture the complexity of language. This is why, depending on the tumor, other tasks such as Counting, Reading, and Translation [58–60], to name a few, have also been used in order to preserve an optimal quality
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of life according to the patient’s specific language requirements. Additional tasks at the sentence/discourse level are needed in the field. Finally, to keep effective communication in bilinguals, a correct capacity for change (language switching) and control (language inhibition) of the different languages is necessary. Most of the studies to monitor language function in bilinguals used the picture naming task. This task seems to tap into single word production. In addition, picture naming has been also used to investigate LS. Participants can be instructed to name the picture in one language (e.g., Spanish) or another language (e.g., English) depending on a specific cue (i.e., the color of the picture frame or a flag, etc.). This way we can compare the responses to trials in which participants have to change the language to name the next picture (switching trials: Picture 1 in Spanish, libro, Picture 2 in English, table) with those in which the same language is used to name two consecutive pictures (repeat trials: Picture 1 in English, book, and Picture 2 in English: table). Error rates and/or reaction times are larger for switching trials as compared to repeat trials. Interestingly, this LS task has been used intraoperatively by the group from Bellvitge, who implemented a LS-electrical stimulation mapping (ESM) paradigm assessment. Their results showed different functional distributions when comparing single-language naming to the LS. Within the frontal lobe, the single language naming sites were found significantly more frequently within the inferior frontal gyrus as compared to the middle frontal gyrus. Contrarily, switching naming sites were distributed across the middle frontal gyrus significantly more often than within the inferior frontal gyrus. These findings support the notion that non-domain-specific cognitive control prefrontal regions (posterior MFG), together with language frontal-related sites (IFG), mediate LS processing in bilinguals [42] (see Fig. 14.1).
14.5 F unctional Improvement in Patients Operated on with Versus Without Function Monitoring ESM studies in bilinguals have yielded heterogeneous results, ranging from a greater spatial representation for L1 [2] or for L2 [21] to an equivalent total cortical surface area involved in L1 and L2 processing, with partially overlapping regions [4] or significantly different anatomical distribution [1]. This spatial separability could imply that testing only one language would put the second language abilities at risk in the postoperative period. There is only one series of bilingual patients operated under LS monitoring using a newly developed LS task that allowed a systematic evaluation of externally triggered LS synchronously with ESM [42]. Based on previous proposals [45], the authors evidenced that the postsurgical neuropsychological scores did not differ significantly from the presurgical ones, and patients did no report involuntary LS in their daily life conversations; however there is no evidence of improvement in comparative cohorts. On the other hand, we are not aware of any study describing a long-lasting deficit for the intraoperatively non-tested language. Nonetheless, as we mentioned in point 2, there are consistent data on global permanent deficits being
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Fig. 14.1 Language functional maps reconstructed on the basis of intraoperative ESM in comparison with neuroimaging results from fMRI in a bilingual patient. Image from the LS-patient series from Sierpowska and Fernandez-Coello [42]
twice more frequent in the unmapped patients undergoing brain surgery for supratentorial gliomas. Numerous papers in the field of ESM in glioma surgery have reported its usefulness to minimize neurological permanent deficits and, at the same time, to improve oncological outcome [40]. It now seems well established that neuro-oncological surgery needs to get to the best balance of quality of life and survival at the same time. Identifying the “connectome” intraoperatively by means of subcortical stimulation has been consolidated as the best tool for this purpose, in a clear new surgical oncofunctional brain surgery philosophy [41, 61–63], but what about not only preserving but improving? As mentioned previously, there are no objective data in the specific field of multilingualism, unlike in the field of global neurocognition. There are no reasons to believe that bilinguals should behave differently. Actually, Duffau already reported a 10% improvement in language skills after surgery of supratentorial LGG in his early series of 103 patients in 2003 [64]. This improvement in language skills is
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even reported for the insular lobe, probably the most challenging area for glioma surgery in awake patients. Duffau reported language improvements in 6 out of 24 patients after insular surgery [65]. These conclusions are shared by other teams, as Pallud et al., who are also reporting up to 30% of language improvement after glioma surgery with ESM [66]. Another neurocognitive aspect of language that is crucial for multilinguals is working memory (see Chap. 12). In particular, working memory capabilities are crucial for daily living, for instance, for a correct and fluid language switching. Recent data from ESM testing working memory before and after oncofunctional surgery preserving the connectome showed that, although 91% of 45 patients experienced working memory loss in the first 3 months, after that time, all 42 patients recovered their preoperative status and 3 of them experienced improvement [67]. Interestingly, these improvements are not only within the neurocognitive sphere; they also have an impact on the patients’ daily life, according to recently published data focusing on returning to their work status, which show that a 97% of them were able to resume their professional practice [68]. The lack of specific comparative series of a possible improvement of multilinguals that had surgery undercover of ESM implies that we cannot conclude that using this technique will improve their language skills. Nonetheless, the data for selective improvement in some patients in all the other neurocognitive aspects mentioned before, and the robust data sustaining the existence of specific functional networks for each language mentioned in the first paragraph of this chapter, partially suggest that oncofunctional surgery may also improve at least one of the languages in some selected patients. In this sense, the increase of functional connectivity observed in peritumoral regions when comparing it 3 months after surgery and before surgery [32] is very promising.
14.6 Closing Remarks The contradictory results in ESM studies testing multiple languages, ranging from a complete overlap among the different languages to spatially distinct and separate areas for each language, lead us to individualize and tailor a neuropsychological protocol testing all the languages the patient fluently speaks or test only their native language, depending on daily needs. The results of ESM-LS studies suggest an executive control functional network that takes advantage both from language-specific areas and non-language cognitive control regions, working together to maintain effective communication. Therefore, testing LS also involves testing non-domain-specific cognitive control networks, resulting in a patient-relevant medical benefit. Finally, the gained evidence from cognitive psychology, neuroimaging studies, and ESM teaches us that the localizationist approach of trying to segregate languages topographically has not yielded conclusive results. Answers possibly lie beyond the cortex, understanding the brain as a dynamic network involving white matter tracts and subcortical structures.
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Acknowledgments This research is supported by the Basque Government through the BERC 2018-2021 program, and by the Agencia Estatal de Investigación through BCBL Severo Ochoa excellence accreditation SEV-2015-0490 and project RTI2018-093547-B-I00.
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Part III Higher-Order Functions
Semantic Cognition
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15.1 Introduction The meaning assigned to words, objects, pictures, sounds, faces, and facts is stored in semantic memory [1, 2]. Stored concepts are thus associated with a number of shared or defining/distinctive features, corresponding to categorical, functional, visual, cultural, and emotional attributes (for instance: the trout is an aquatic animal, living in fresh water, I don’t know how to fish trout, I like its taste, Schubert composed a quintet named the trout). Semantic knowledge then supports many everyday activities, and is critical for both verbal and nonverbal behaviors. However, an efficient semantic processing not only requires to access this store of conceptual knowledge, but also to activate adequately relevant stored information, in a goal- directed manner. Semantic cognition designs these neurocognitive processes enabling to organize, generalize, and manipulate efficiently semantic representations, thanks to the involvement of control mechanisms [2–4]. Current neuro-computational models of semantic cognition arise from nearly five decades of studies on acquired semantic impairments among which pioneering works highlighted notably the phenomenon of modality-specific and category- specific semantic deficits [5, 6], generating by the way different assumptions about the organization of conceptual knowledge in the brain, suggesting either that different semantic categories are represented or not in dissociable brain areas, depending or not on modality-specific input/output (for a review, see [7]). A number of questions in this topic are still a matter of striking debate, the most controversial being thus probably whether semantic knowledge is represented in distributed isolable— even if connected—brain areas or in a unified amodal hub. A convincing and S. Moritz-Gasser (*) · G. Herbet Institute of Functional Genomics, INSERM U1191, Team “Plasticity, Stem Cells and Glial Tumors”, University of Montpellier, Montpellier, France Gui de Chauliac Hospital, Montpellier, France e-mail: [email protected] © Springer Nature Switzerland AG 2021 E. Mandonnet, G. Herbet (eds.), Intraoperative Mapping of Cognitive Networks, https://doi.org/10.1007/978-3-030-75071-8_15
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reconciling answer is brought by the “distributed-plus-hub” view [1], described by the hub-and-spoke model in which modality-specific aspects of conceptual knowledge shaping the organization of semantic memory in distributed brain areas are integrated in a transmodal anterior temporal hub encoding generalizable higher- order conceptual representations by mediating cross-modal interactions between these sources of information [3]. In the setting of the hub-and-spoke model, the controlled semantic cognition (CSC) framework refers to how this conceptual knowledge is adequately activated, in a goal-directed manner, thanks to the interaction of a semantic control system relying on executive mechanisms, which constrains semantic representation activations depending on the task at hand, whether verbal or nonverbal (for example, different semantic attributes associated with the concept “trout” will have to be activated depending on the situation: accessing the name of this fish, preparing a meal, fishing, painting, or listening to Schubert’s work). CSC framework further accounts for different patterns of semantic impairments observed in various neurological conditions such as loss of semantic knowledge reported in semantic dementia (SD), related to a degradation of the semantic system itself, or semantic access deficit reported in stroke aphasia, likely reflecting impairments of the semantic control system [8–11]. Studies aiming to compare patterns of semantic impairments between SD and stroke aphasia patients have indeed provided a number of differences in both verbal and nonverbal domains, patients with stroke-induced semantic impairments exhibiting notably, in contrast with SD-induced semantic impairments, inconsistent results across tests, no effect of frequency or familiarity of stimuli, and strong effect of cueing on task performance [12, 13]. By bringing meaning to most of everyday situations, semantic cognition is then critical for verbal and nonverbal human behaviors, and disorders in semantic processing have thus extremely debilitating consequences. Needless to say, semantic cognition, as a defining feature of human being, should imperiously be thoroughly monitored during intraoperative awake surgery mapping, with full up-to-date knowledge of its neural bases, in order to avoid long-lasting verbal and/or nonverbal semantic impairments.
15.2 N eural Bases of Semantic Cognition: State of Knowledge Neural bases of semantic cognition have been addressed in a large number of clinical studies analyzing patterns of brain damage in patients and functional neuroimaging-based studies, in patients and healthy volunteers (e.g., [14–20]), suggesting a broad distributed neural representation, mostly but not exclusively left lateralized. A recent meta-analysis of 120 functional neuroimaging studies reported a network of 7 left-sided loci involved in semantic processing [21], namely the posterior inferior parietal lobe, especially the angular gyrus (post IPL, AG), the middle and posterior inferior temporal gyri (MTG and ITG), the mid-fusiform and parahippocampal gyri, the dorsomedial prefrontal cortex (DMPFC), the inferior frontal
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gyrus (IFG), the ventromedial prefrontal cortex (VMPFC), and the posterior cingulate gyrus. It is worth noting here that, because the goal of this meta-analysis was to identify brain regions involved specifically in semantic processing, the authors excluded studies employing contrasting tasks that differed in terms of difficulty, in order to identify only semantic areas and not regions involved in more general cognitive processes required in any goal-directed task. However, some studies show that a number of control processes mediated by the left inferior prefrontal cortex (LIPC) and temporo-parietal cortices (notably pMTG and AG) are specifically engaged in goal-directed retrieval of semantic knowledge per se [4, 22–27], indicating that these regions should be identified as belonging to the semantic network. Furthermore, semantic dementia (SD), a neurodegenerative disease marked by a progressive loss of semantic knowledge in all modalities with well-preserved other aspects of cognition, that is a selective impairment of semantic abilities [28, 29], is associated with a bilateral—albeit often asymmetrical—degeneration of the anterior temporal lobes (ATLs), especially in their ventral portion [30–34], suggesting that these regions act as semantic hubs, supporting the formation of amodal semantic representations [1, 35, 36]. Conceptual knowledge would then be represented in an amodal fashion bilaterally in the ATLs, explaining why unilateral ATL damage due to stroke or resection typically does not result in such profound semantic impairments as those encountered in SD patients [37, 38]. This bilateral representation of course does not mean that the two ATLs are equipotent in semantic processing, but rather that they work jointly to process semantic information and that the effects of unilateral damage might be at least partially compensated by the contralateral system, with however slowing of reaction times and poorer performance in particularly demanding semantic tasks [39]. Further studies suggest besides that activations are more likely to be left lateralized to process verbal input or when word retrieval is required and for the processing of distinctive vs. shared semantic features [40, 41], and that pictorial semantic processing is less affected than verbal semantic processing following unilateral ATL resection, because it draws on a bilateral network [42]. Finally, it is now well established that this widely distributed semantic network is underlain by a bilateral ventral white matter connectivity involving the inferior fronto-occipital, inferior longitudinal, and uncinate fasciculi (IFOF, ILF, and UF) [43–51]. In this setting, some authors (e.g., [52]) suggest that this ventral semantic stream would consist of a critical direct route sub-served by the IFOF, connecting occipito-temporo-parietal cortices to inferior frontal and dorsolateral prefrontal cortices [53], and an indirect route, likely to be compensable in case of unilateral damage, sub-served by the anterior part of the ILF and the UF, connecting respectively the posterior temporo-basal cortex to the temporal pole, and the temporal pole to the pars orbitalis of the IFG [54]. Indeed, left IFOF has been shown to crucially support verbal as well as nonverbal semantic processes, since intraoperative direct electrical stimulation (DES) of this fasciculus entails both transient verbal semantic impairments (production of semantic paraphasia during naming task) and nonverbal semantic deficits (inability to associate two visually presented concepts) [47], whereas the indirect pathway (ILF/UF) can be functionally compensated when
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unilaterally damaged, as demonstrated following anterior temporal and orbitofrontal glioma resections [55, 56]. Of note, given its connections with components of the limbic system, namely amygdala and para hippocampal gyrus [57], this parallel indirect pathway has further been suggested to be involved in emotional-valued semantic processing [58, 59]. Interestingly, studies based on the Klingler fiber dissection technique identified in the IFOF a superficial dorsal subcomponent, connecting the superior and middle occipital gyri, the superior parietal lobule, and the posterior part of the STG to the IFG, and a deep ventral subcomponent, connecting the inferior occipital gyrus, the posterior temporal-basal area and the posterior part of the MTG to the orbitofrontal cortex, middle frontal gyrus, and dorsolateral prefrontal cortex [60], suggesting a possible anatomo-functional segregation of this fasciculus, the superficial layer being involved in verbal semantics and the deep one in amodal and control semantic processes, and possibly in the awareness of semantic knowledge [47, 61]. Studies based on intraoperative mapping, as detailed in subsequent parts of this chapter, contribute highly to shed light on the neural bases of semantic processing, emphasizing especially, in addition to the above-described left-lateralized semantic network, the implication of a right-lateralized network.
15.3 Semantic Impairments in Brain Tumor Patients Crucial for language production and comprehension as well as nonverbal human behaviors, semantic cognition is supported by a broad distributed neural representation. As a defining feature of human being, verbal and nonverbal semantic cognition should then be thoroughly assessed perioperatively and monitored during intraoperative awake surgery mapping, in order to avoid long-lasting dramatically debilitating impairments. Yet, because semantic processing is so far not routinely fully assessed [62–64], it should be acknowledged that studies reporting semantic disorders in brain-damaged patients in general and in brain tumor patients in particular are scarce, and focus mainly on verbal semantics. Thereon, a recent study aiming to characterize language impairments in brain tumor patients thanks to a specific language assessment based on the analysis of cognitive processes involved in language processing (BLAST: Brief Language Assessment for Surgical Tumour Patients) highlighted the existence of preoperative disorders in accessing semantic knowledge (assessed notably through picture naming, picture-word verification, and verb generation) in these patients compared to healthy controls [65]. Interestingly, these disorders were present mostly in patients with left-lateralized frontal, temporal, and parietal tumors, but also, although in a lesser extent, in patients with right-lateralized tumors. A case series study, aiming to validate the Dutch Linguistic Intraoperative Protocol (DuLIP), suggested further that by monitoring lexical-semantic processes intraoperatively, especially by the means of a semantic odd word/picture out task and a semantic association task, lexical-semantic disorders potentially observed during the immediate postoperative period (e.g., [66]) may resolve 6 months postoperatively [67]. Furthermore, a study aiming to distinguish semantic access
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disorders from semantic memory degradation in patients with brain tumor located to the temporal lobe showed that whenever (pre- and/or postoperatively) semantic deficits emerged, they were clearly of access type (i.e., inconsistency of concept activation and performance weakly affected by word frequency) and that high-grade tumors regularly impaired access to semantic representations, whereas low-grade tumors did not [68]. Importantly, the same type of semantic access disorders has been reported after surgical resection of a glioma infiltrating the left dorsal and ventral prefrontal cortices and underlying white matter, thus sparing the temporal lobe but disrupting efficient access to semantic representations [66].
15.4 N etworks at Risk for Semantic Cognition in Glioma Surgery While the study of semantic cognition has been the target of numerous works in certain neuropathological conditions, attempts to determine which cortical or subcortical structures might be especially vulnerable to resective surgery have been very limited in the context of glioma. Yet this knowledge is absolutely vital for the care of patients since results from lesion studies are not completely transposable from one brain condition to another due to differing physiopathological mechanisms (and associated neuroplasticity potential). To the best of your knowledge, only two studies employing voxelwise brain-behavioral analyses are available in the current literature. The first of them [43] focused on the behavioral performances obtained on a task assessing semantic and phonological fluency. In this study, 31 patients with a histologically proven diffuse low-grade glioma infiltrating the left hemisphere were included. Patients were examined before surgery, 4–5 days after and then 3 months after surgery. Mass-univariate voxel-based lesion-symptom (VLSM) mapping analyses were conducted on the behavioral performances gained at each time point. Interestingly, before patients had been operated on, the performance on the semantic fluency task was associated with a large amount of voxels mainly situated in the white matter underlying the ventral system. Further analyses showed that these correlated voxels greatly overlapped with the typical course of the left IFOF. As a matter of fact, a significant correlation was obtained between semantic fluency score and the amount of tumor infiltration into the IFOF. No significant results were obtained with the phonological fluency task. After surgery, no brain-behavior relationships were identified for both tasks and for the two postoperative periods, suggesting that the surgery in itself did not lead to additional and permanent difficulties. Note that all patients were operated on under awake conditions with a mapping of semantic processes allowing the IFOF to be spared from the surgical procedure. In sum, progressive tumor infiltration of the left IFOF is associated with declining performances in terms of semantic fluency but, in turn, sparing the IFOF during surgery helps to maintain the level of performance after surgery. This general finding cannot be, however, generalized as only one specific aspect of semantic cognition was assessed.
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In the second study [69], 66 patients operated on in awake surgery but with different etiologies (including WHO II, III, and IV grade glioma, arteriovenous malformation and cavernous angioma, lymphoma and metastasis) were assessed preoperatively with a range of neuropsychological tasks, including tasks tapping into the processes of semantic cognition (i.e., a naming task, a synonym judgment task, and a semantic matching task). Standard VLSM and tract-oriented lesion- symptom analyses were performed. First, VLSM failed to identify any relationships between the location of lesions and performances obtained on the synonym judgement and the semantic association task. However, a large bulk of significant voxels was found for the naming task, mainly in the ITG and the MTG and their underlying white matter connectivity—thus widely replicating the findings from Herbet et al. [70] (see also Chap. 5). Second, trackwise analyses indicated that naming performances in general were correlated with the amount of damage of the three ventral white matter tracts (i.e., the IFOF, the ILF, and the UF), but only the number of semantic paraphasias correlated with the IFOF. Furthermore, scores of the association semantic task specifically correlated with the left IFOF. Taken together, the results confirmed that left IFOF damage is especially deleterious for both verbal and nonverbal semantic cognition, as demonstrated in a previous work using electrostimulation mapping [47]. It is worth mentioning here that, to date, no study has been performed to assess semantic cognition in a comprehensive manner using a longitudinal experimental design. As a consequence, it is unknown whether damage to the cortical structures classically belonging to the semantic network (such as, for example, the IFG and the MTG) may cause permanent deficits in specific or multiple aspects of semantic cognition. In the same way, it remains unknown whether surgically related damage to the UF, ILF, or IFOF is associated with marked semantic deficits. This lack of data should prompt us to plan studies to ascertain the extent to which the processes of semantic cognition may be impaired despite a mapping of some of them. This is the only way to decide whether or not other behavior tasks than those usually employed (see the next section) should be envisioned for the intraoperative mapping [71].
15.5 Intraoperative Monitoring of Semantic Cognition As mentioned above, whereas semantic cognition supports verbal as well as nonverbal behaviors, it is still not routinely fully assessed and when it is, solely through verbal tasks. In this regard, a number of authors proposed intraoperative examinations of language including lexical semantics (e.g., [64, 65, 67, 72–74]), which proved their value by highlighting broadly their sensitivity in detecting lexical-semantic transient disorders intraoperatively induced by DES, and consequently the absence of long-lasting postsurgical lexical-semantic disorders. These batteries assess verbal semantic processing by means of different tasks such as
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picture naming, semantic odd word/picture out, picture-word verification, verb generation, word-to-picture matching, or synonym judgement. However, intraoperative monitoring of semantic cognition cannot be limited to verbal semantics and a broader assessment of conceptual knowledge is needed, as emphasized in a recent electrical stimulation and lesion-symptom mapping study [69], as well as in previous works on SD, stressing the importance of assessing semantic knowledge in both verbal and nonverbal modalities of input/output [75, 76]. Finally, a few studies described besides a dissociation between naming and comprehension (notably preserved naming despite poor comprehension assessed by means of word-picture matching or semantic association tasks, the reverse situation being largely more common), emphasizing the necessity to assess conceptual knowledge in addition to naming, in order to detect a possible impairment in the former especially when the latter is preserved [77–79], and to specify the nature of the semantic impairment underlying the production of semantic paraphasias during intraoperative naming [47]. In sum, intraoperative monitoring of semantic cognition should include at least, in addition to pointing out semantic errors in picture naming, a nonverbal semantic association task (e.g., pictures version of the Pyramids and Palm Trees Test—PPTT, [80]) enabling to assess the ability for the patient to retrieve semantic and conceptual information from pictures, and then to indicate whether a given semantic impairment is dependent or not on the modality of processing. Given that neural bases of semantic processing are broadly distributed, this intraoperative assessment of nonverbal conceptual knowledge should be performed whatever the location of a tumor invading the left and right ventral routes, cortically and subcortically, especially at the level of the IFOF and its cortical terminations [53, 60]. Pre- and postoperatively, a more comprehensive battery of semantic cognition assessment should be used, including verbal and nonverbal tasks varying in complexity (that is requiring various levels of semantic control) such as, in addition to picture naming and word/picture semantic association, word-to-picture matching, picture/word sorting, semantic feature verification, sound recognition, verb generation, synonym judgement, and category fluency (compared to letter fluency), in order to build up thoroughly and as accurately as possible the semantic profile of the patient at both times of evaluation, and to design consequently specific and individualized rehabilitation programs if needed. Of note, some existing batteries propose a number of these tasks using the same items across them, controlled for category, frequency, and imageability, allowing a fine-grained analysis of semantic impairments in verbal and nonverbal modalities (e.g., CSM battery, [75]; BETL, [81]; BECS, [82]). These extensive evaluations, confronted with a standard neuropsychological assessment, could allow to implement longitudinal studies addressing long-term outcomes concerning semantic cognition and subsequently the clinical relevance of adding adapted new intraoperative semantic tasks, guided by the onco-functional balance, that is the challenging goal of maximizing the extent of resection while preserving the quality of life [83].
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15.6 W hich Additional Anatomo-Functional Knowledge Has Been Gained from Intraoperative Mapping Studies? As mapping the language system with an object naming task has been the “gold standard” in awake surgery for a long while, data on the cortical organization of the verbal semantic system gained from electrostimulation mapping has accumulated over time, with the advantage of revealing the interindividual differences into the neural implementation of this system—contrary to other imaging modalities such as activation MRI. For example, in two successive stimulation-based probabilistic atlases [84, 85], sites for verbal semantic cognition (i.e., anatomical loci associated with semantic paraphasia) were identified in the anterior-to-posterior part of the STG and the most posterior portion of the MTG posteriorly, and in the pars triangularis and opercularis of the IFG, and the posterior dorsolateral prefrontal cortex anteriorly (Fig. 15.1). In the same way, based on the stimulation data of patients with diffuse low-grade glioma in whom semantic loci were found in the prefrontal cortex (left and right hemisphere), Herbet et al. [86] identified 45 verbal semantic sites that were equally distributed in pars opercularis and pars triangularis of the IFG as well as in the posteriormost portion of the dorsolateral prefrontal cortex (Fig. 15.2a, b). The entire cortical surface of these areas was covered, demonstrating a large interindividual variability. Interestingly, in this work, nonverbal semantic sites, as identified with the PPTT, were also processed. The analysis revealed this time a bilateral representation mainly involving the posterior dorsolateral prefrontal cortex with minor engagement of the IFG (Fig. 15.2c, d). Once again, there was a certain degree of interindividual variation in the location of sites, as they differed topologically along both a rostro-caudal and a dorsoventral axis. At the subcortical level, critical insights into the white matter connections that might be involved in broadcasting semantic-related signals have been gained from electrostimulation mapping, this technique being the sole to allow direct inferences into the functions of white matter tracts [87]. In a first work by Duffau et al. [44], white matter sites associated with verbal semantic processing (obtained from 17 patients operated on under local anesthesia for left low-grade glioma) were considered conjointly. They were distributed in the white matter under the depth of the superior temporal sulcus, in the anterior floor of the external capsule and in the white matter deep in lateral orbitofrontal and dorsolateral prefrontal regions, a distribution that widely overlaps with the spatial course of the IFOF. This was the first demonstration that the IFOF may constitute the white matter connectivity underlying the ventral stream for semantic processing [46]. This finding was replicated by the same group a few years later but a new result was also provided [47]. The authors showed that transitory inactivation of the left IFOF not only disrupted verbal semantic processing but also nonverbal semantic processing as assessed by the PPTT. Furthermore, some sites were associated with both verbal and nonverbal semantic impairments, whereas other ones were uniquely associated with verbal semantic impairments, suggesting a bipartite functional organization of the IFOF. More specifically, in view of the multilayered structure of the IFOF evidenced by diffusion MRI and dissection studies (e.g., [60, 88, 89]), the
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Fig. 15.1 Linguistic components of naming and summary map of cortical stimulation data. (a) Raw stimulation data and corresponding clusters for phonological (pink) and semantic (black) aspects of naming in right-handed patients. Phonological epicenters were located in the middle superior temporal gyrus, pars opercularis, and junction of precentral/dorsolateral prefrontal cortex. Three semantic nodes were identified: junction of posterior superior temporal gyrus and supramarginal gyrus, pars triangularis/opercularis, and dorsolateral prefrontal cortex. (b) Compilation of all stimulation data (n = 771 stimulation sites) in the right and left hemisphere demonstrating the wide distribution of cortical representation within and between critical functions of the human brain: motor (green), sensory (yellow), anarthria/arrest (red), anomia (blue), dysarthria (orange), phonological (pink), semantic (black). L left hemisphere only. Reused with permission from Tate et al. [85]
authors postulated that the superficial layer of the IFOF may be involved in verbal, modality-specific semantic processing, whereas the deep one may be rather involved in multimodal semantic processing [61]. This hypothesis needs, however, to be firmly supported by further experimental evidence. In another study by Herbet et al. [90], direct evidence for the role of the right IFOF in nonverbal semantic cognition, assessed by means of the PPTT, was provided. In particular, 13 patients having undergone an awake surgery for a right
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Fig. 15.2 Anatomical sites associated with (a) semantic paraphasia in the left frontal lobe, (b) semantic paraphasia in the right frontal lobe, (c) a disturbance of nonverbal semantic cognition in the left frontal lobe, and (d) a disturbance of nonverbal semantic cognition in the right frontal lobe. Blue circles: sites associated with semantic paraphasia; green circles: sites associated with nonverbal semantic disturbances; yellow circles: amodal site (i.e., associated with both semantic paraphasia and nonverbal semantic sites). IFGoper pars opercularis of the inferior frontal gyrus, IFGtri pars triangularis of the inferior frontal gyrus, MNI Montreal Neurological Institute, pDLPFC posterior dorsolateral prefrontal cortex. Reused with permission from Herbet et al. [86]
diffuse low-grade glioma were included. Positive sites were observed in the white matter of the angular gyrus and of the middle and superior temporal gyri, in the temporal stem, and in the white matter of the dorsolateral prefrontal cortex—a distribution that widely overlaps with the IFOF according to most of the anatomical studies (Fig. 15.3). This finding confirms that the nonverbal semantic network has a homotypic organization at the white matter level, as suggested by Herbet et al. [86] at the cortical level. Finally, Sierpowska et al. [69] used conjointly a naming task, a semantic pair task, and a semantic association task to map white matter tracts involved in some
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aspects of semantic cognition. Globally, the authors found an involvement of both the left IFOF and the left ILF in the three tasks, but no precise anatomo-functional correlation analyses were performed on the intraoperative data. In sum, electrostimulation mapping studies in awake patients were the first to allow to characterize the white matter pathways of the semantic network, in particular the central involvement of the IFOF in the left and the right cerebral hemispheres, a finding that has been now strengthened in neuropsychological studies using voxelwise lesion-symptom analyses (e.g., [91]).
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15.7 Conclusion Semantic cognition is a defining feature of human being, essential for verbal and nonverbal behaviors, involving numerous sub-processes supported by a broad distributed neural representation. As such, verbal and nonverbal semantic cognition should then be thoroughly assessed perioperatively and monitored during intraoperative awake surgery mapping, cortically and subcortically along the ventral route, especially at the level of the IFOF and its cortical terminations, in both hemispheres, in order to avoid long-lasting debilitating impairments. Intraoperative monitoring of semantic cognition should thus include at least, in addition to pointing out semantic errors in picture naming, a nonverbal semantic association task. Pre- and postoperatively, a more comprehensive battery of semantic cognition assessment should be used, including existing verbal and nonverbal tasks varying in complexity. These extensive evaluations, by drawing up the semantic profile of the patient at both times of evaluation, would allow, on the one hand, to design individualized rehabilitation programs, and, on the other hand, to implement longitudinal studies addressing long-term outcomes concerning semantic cognition and subsequently the clinical relevance of adding adapted new intraoperative semantic tasks, guided by the onco-functional balance aiming at maximizing the extent of resection while preserving the quality of life.
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Inhibition
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Jérôme Cochereau, Michel Wager, Marco Rossi, Antonella Leonetti, Tommaso Sciortino, Lorenzo Bello, and Guglielmo Puglisi
16.1 Introduction Awake surgery of brain tumors has led to a paradigmatic shift consisting of an increased interest in assessing the functional consequences of surgical procedures. It has clearly demonstrated its great effectiveness in preserving functions supported by primary or unimodal cortex. However, only a few studies have focused on the value of awake surgery to preserve higher order functions such as executive functions. Inhibition is a pervasive cognitive control process, needed in many everyday life situations, and particularly when threatening events occur, such as holding back the suction device while operating a patient who starts producing errors to peroperative tests during an awake surgery. Subjects with impaired inhibitory control can present with impulsivity, perseverative behavior, and distractibility [1–4]. It has been implicated in multiple psychopathological conditions such as attention deficit hyperactivity disorder and obsessive compulsive disorder [5]. The purpose of this chapter is to provide the reader a comprehensive understanding of inhibitory control
J. Cochereau · M. Wager (*) Neurosurgery Department, Poitiers University Hospital, Poitiers, France e-mail: [email protected]; [email protected] M. Rossi · T. Sciortino · L. Bello Department of Oncology and Hemato-Oncology, Università degli studi di Milano, Milan, Italy Neurosurgical Oncological Unit, IRCCS Istituto Ortopedico Galeazzi, Milan, Italy e-mail: [email protected]; [email protected] A. Leonetti · G. Puglisi Neurosurgical Oncological Unit, IRCCS Istituto Ortopedico Galeazzi, Milan, Italy MOCA Lab, Department of Medical Biotechnologies and Translational Medicine, Università degli Studi di Milano, Milan, Italy e-mail: [email protected] © Springer Nature Switzerland AG 2021 E. Mandonnet, G. Herbet (eds.), Intraoperative Mapping of Cognitive Networks, https://doi.org/10.1007/978-3-030-75071-8_16
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processes applied to neurosurgical patients and to initiate a discussion on the relevance of peroperative inhibition monitoring during awake surgery.
16.2 Neural Basis of Inhibition 16.2.1 Definition Inhibitory control, as part of the three core executive functions (EF), i.e., cognitive flexibility, inhibition, and working memory [1, 2], corresponds to multiple taxonomies. However, one commonly admitted segregation of this multifaceted concept is to consider inhibition as a twofold concept comprising behavioral and cognitive inhibition [2, 3]. The former refers to response inhibition, deferred gratification, and reversal learning while the latter relates to the inhibition of prepotent memories, perceptions, thoughts, and emotions. Response inhibition is by far the most studied phenomenon as it can be easily experimentally implemented in motor response inhibition paradigms that involve the inhibition of prepotent and automatic motor responses. According to the taxonomy we employ, interference control, i.e., the cognitive control needed to prevent irrelevant stimuli to interfere with a goal- directed behavior, can be part of both types of inhibitory control described above or considered as a separate type of inhibitory control process [4].
16.2.2 Inhibition Tests In clinical settings, diverse tests address inhibitory mechanisms, though whether such tasks isolate processes of response inhibition remain controversial, as opposed to related processes such as response selection, conflict resolution, attention, and working memory [5]. For the purpose of our chapter, we briefly recall the main features of some of the commonly used tests. Motor response inhibition is frequently assessed by the go- no-go and the stop-signal reaction-time tasks. Interference control can be evaluated by the Stroop color-word interference test and the Eriksen flanker task. In a go-no-go task, a cue tells participants to respond or withhold responding to “go” and “no-go” stimuli, respectively. The more frequent the go trials, the higher the prepotency of the response and the errors likelihood. In the stop-signal reaction-time task, go trials require responding to arrows pointing right or left. In some of the trials, the go signal is followed after a variable delay by a “stop” signal that requires participants hold their response [6]. It is a measure of speed of inhibition. Task variations—including changing the probability of stop signals, influencing the participant’s certainty of go trials, or using selective- stopping trials—alter the balance of engagement of proactive versus reactive strategies. In the Stroop color-word interference test, participants name the ink colors of color words that are printed in concordant or discordant ink. The delay in reaction
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time between congruent and incongruent stimuli, namely the Stroop effect, is influenced by the process of inhibition of the prepotent response [7]. During an Eriksen flanker task, the subject is asked to indicate the direction the center arrow is pointing as quickly as possible, while ignoring flanking arrows that, on some trials, point in the opposite direction. Reaction times are faster when the response indicated by the central stimulus is consistent with the response indicated by the flanking stimuli than when these are incompatible [8]. It reflects the process of interference inhibition.
16.2.3 Neural Substrates of Inhibition 16.2.3.1 N eural Processes in Behavioral and Cognitive Inhibition. Same or Different? There has been much debate in the field of inhibitory control neuroscience about the very existence of inhibitory processes in what is called cognitive inhibition [9, 10] whereas behavioral inhibition is readily accepted as an inhibitory process, and as a consequence, the generalizability of behavioral inhibition models to cognitive inhibition is not straightforward [11, 12]. To challenge that question, although cognitive inhibition is not as readily studied as motor inhibition due to the absence of overt behavioral measures, several studies have assessed the differences and similarities between these two phenomena thanks to the design of “cognitive” versions of the go-no-go test. For example, based on a “Think/no think” procedure [13], Anderson et al. evidenced a bilaterally increased activation of a cognitive control network, and especially the dorsolateral prefrontal cortex (DLPFC), a region formally known to participate to response inhibition [14], along with a deactivation of the hippocampus during trials where the subjects were asked to inhibit thoughts [15]. In their review, although they mention different prefrontal areas specifically implicated in diverse types of cognitive inhibition processes (namely the orbitofrontal cortex and the ventromedial prefrontal cortex, respectively associated with inhibition of cognitive sets and fear extinction), Dillon and Pizzagalli underline the implication of the right ventrolateral prefrontal cortex (VLPFC) in all types of inhibition processes [16]. In line with that observation, a more recent experience carried out by Tabibnia et al. using voxel-based morphometry on patients suffering from methamphetamine dependence compared to controls showed first that motor and affective inhibitory control in these patients were correlated and second that inhibitory control scores correlated to the right pars opercularis gray matter intensity [17]. To conclude, it would appear that cognitive and behavioral inhibition share overlapping processes distributed in the same cortical areas, i.e., the DLPFC and the right VLPFC, but also involve various additional cortical regions according to the inhibited cognitive function at hand [3]. Consequently, the study of response inhibition can shed a light on the key neural processes at play in inhibition. Moreover, as response inhibition can be rather easily implemented in an awake surgery paradigm [18, 19], the rest of that subchapter will focus on experimental results emanating from studies of response inhibition.
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16.2.3.2 Neural Basis of Response Inhibition The Modular Theory of Inhibition The go-no-go and the stop-signal reaction-time tasks are both widely represented in response inhibition studies. These tasks, applied to patients with prefrontal cortex damage, drew attention on two regions correlated with delayed reaction time or errors in no-go trials, i.e., the right VLPFC [20] and the dorsomedial prefrontal cortex, namely the pre-supplementary motor area (pre-SMA) [21, 22]. These lesion studies have been supplemented by neuroimaging and neurodisruption experiments that confirmed the implication of both cortical areas in response inhibition [14, 23– 26]. Together with those two key regions, premotor cortex, DLPFC, parietal cortex, insula, and basal ganglia seem to all be implicated in inhibitory control [22, 26–30]. The inhibitory subprocess carried by the right inferior frontal cortex (IFC) is equivocal and Aron stipulated that the right IFC could suppress basal ganglia outputs, probably via the subthalamic nucleus [12]. Rather than the sole activity of the IFC, a more elaborated theory suggested that the interplay between the right IFC and the pre-SMA leads to the suppression of ongoing motor plans via their mutual and respective connectivity with the subthalamic nucleus (STN) [31]. Interestingly, Duann et al. showed, using Granger causality, that the IFC, as part of the ventral attention system, could respond to stop signals and subsequently synchronize with the pre-SMA, involved in goal-directed behavior, that exerts its modulatory effect on the STN to pause a prepotent response [32]. Parietal cortex is naturally involved in response inhibition as visuospatial attention is constantly requested and modulated by the top-down effects of the prefrontal cortex [28]. The DLPFC has been identified as a pivotal hub of the cognitive control network [33], and its participation to response inhibition can be likened to maintenance of task rules in working memory as its level of activation has been related to increased working memory load [14, 29]. Activations of the insular cortex are also observed and can be related to interference resolution processes when conflicting responses are activated [34, 35]. The Role of the Left Hemisphere in Inhibitory Control As defective response inhibition can be observed after a left hemisphere damage [36], the lateralization of response inhibition is strongly debated [3]. Indeed, the left IFC has been implicated in rule maintenance and retrieval [37] which is necessary for response inhibition efficiency, as demonstrated by Hirose et al. who correlated brain activity with the subjects’ performances in go-no-go trials, revealing a left-sided cortical network encompassing notably the IFC and the inferior parietal cortex [38]. The Network Perspective on Inhibitory Control More recently, the theory of inhibitory modules in the prefrontal cortex has been challenged. More specifically, the right IFC is no longer considered as a region involved in inhibitory control but rather an area belonging to the multiple
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demand system [39] with no specificity for inhibition. In that respect, inhibition would just be an example of the cognitive control processes supported by the same set of “domain general” functional networks [40]; hence inhibition would not rely on a dedicated network. Cortical regions that are “domain general” have the ability to rapidly adapt to support a variety of novel or demanding tasks [41]. In their review, by concatenating results of researches on various forms of cognitive control, Hampshire and Sharp make the assumption that domain general networks exert control by modulating local inhibitory connections (known as lateral inhibition) [42]. Neurons from the multiple demand system have the specific capability to rapidly switch in multiple states and subsequently settle into a stable low-activity state which adapts in function of the current task-relevant rule [43]. According to their theory, in the face of a nonroutine task, the multiple demand system is warned, resulting in a temporary program coding for topdown signals that will potentiate task-relevant processes in visual and motor areas according to the current task-relevant rule. Competing processes, including routine automatic motor responses, are then downregulated via lateral inhibition. This theory accounts well with the fact that right IFC/anterior insula activations during a stop-signal task attenuate sharply as the task becomes more familiar [41]. White Matter Correlates of Inhibition Processes As discussed above, inhibition is a component of cognitive control processes that relies on widely distributed networks; hence a well-organized long range structural connectivity subserving those networks is mandatory to ensure efficient control. This white matter connectivity is not yet well described though this knowledge is crucial to anyone who aims to preserve those functions per operatively. In Aron’s modular framework, it has been hypothesized that the right IFC, pre-SMA, and subthalamic nucleus were one by one connected leading to a functional and structural core for inhibition [31]. By controlling for processing speed in a go-nogo task, Hinton et al. found a significant correlation between the right IFG and STN structural connectivity and task performance [44]. The tract that connects IFC and pre-SMA is consistent with the frontal aslant tract (FAT); hence it has been suggested that the right FAT could play a role in inhibitory control [45], but this hypothesis has been challenged by the results of white matter direct stimulations that have highlighted the role of fronto-striatal tracts rather than the FAT [46]. Finally, given the fact that inhibition is a bilaterally represented process and that it relies on frontoparietal top-down modulations, both the corpus callosum and frontoparietal tracts should be involved. As a matter of fact, a correlation has been evidenced between an inhibition and both the corpus callosum and cingulum bundle [19, 47]. Moreover, the superior longitudinal fasciculus that connects the lateral aspects of frontal and parietal lobes seems to contribute to interference resolution processes [48].
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16.3 E vidence of Long-Term Deficits in Patients Who Did Not Benefit from Intraoperative Inhibition Monitoring Except in some rare neurosurgical centers [18, 19], executive function monitoring is not routinely performed during awake surgery [49]; hence one may interrogate if patients frequently suffer from inhibition impairment following such surgeries. That is, of course, an important question because it determines the need for such a monitoring if inhibition deficits frequently occur. Besides, determining the exact impact of surgery on inhibition performance is challenging as studies interested in neuropsychological outcome after brain surgery readily refer to “executive functions” in general rather than its specific subcomponents. The delay between surgery and neuropsychological assessment is another important factor as executive functioning may improve or worsen between two postoperative timepoints. Indeed, executive functions worsening can be expected early after surgery (3 months) and can recover, at least partially, 6 months after surgery [50]. On the contrary, Satoer et al. reported interference inhibition worsening 1 year after surgery compared to 3 months after surgery although no worsening at 3 months post-surgery compared to the preoperative status was reported [51]. Those inconsistent findings may account for cohort inhomogeneities in terms of surgical results, natural disease evolution, and evaluation timing. Although awake surgery (without executive functions mapping) readily leads to less (though not avoiding) postoperative executive dysfunctions than asleep surgery according to a recent meta-analysis [52], some other authors argue that it is more prone to cause deficits (notably in the Stroop test) as awake surgery leads to more extensive resections blinded from the unscreened functions [53]. The rationale of inhibition monitoring has been explored as a tool to preserve executive functions by Puglisi et al. as at 3 months after surgery, in a subset of 45 patients operated from a frontal nondominant hemisphere glioma, they showed a raised prevalence of executive dysfunctions of 22% and 61% in the Stroop monitored and Stroop non-monitored groups, respectively (statistically significant difference) [18]. However, executive dysfunction also occurs when tumors are located in the dominant hemisphere and/or in non-frontal regions [54]. To conclude, the actual literature provides some evidences of long-lasting surgically related inhibition deficits, but the real impact of those deficits in terms of quality of life, though addressed in other clinical populations, remains to be addressed in brain tumor patients.
16.4 R eview About Knowledge Gained from Lesion-Symptom Mapping 16.4.1 Eligibility Criteria of Publications for This Research Studies of patients with ischemic stroke or head injury were excluded as they did not allow a sufficiently precise definition of the affected anatomical regions and
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structures, and therefore no pathophysiological inferences. We have also discarded studies that explicitly evaluated global executive functions—usually conducted in these same patients. Finally, animal studies were discarded for fear that the conclusions drawn in animals—even primates—would not lend themselves well to extrapolation to humans for the function at hand. As a result of these limitations, only eight studies in the literature were found to meet all of these criteria. Finally, one of these studies [55] is not precise enough in its description of the cortical areas concerned to integrate it into the discussion in hodological terms. It was therefore not taken into account in the discussion.
16.4.2 Studies Involving a Single Cortical Lesion Site per Patient The main characteristics of the selected studies appear in Table 16.1. These studies document an initial finding, which is that a single cortical lesion may be associated with lasting impairment—up to several years—of at least one aspect of executive function, namely inhibition. However, according to Lashley’s principle of mass action, a focal lesion of a non-primary cortex has no noticeable functional repercussion, and especially not a lasting one [56]. However, the areas cited in these studies are not primary areas. On the other hand, these studies establish associations, which is not causality. Thus, the lasting nature of the observed deficits raises the question of the effect not of the cortical lesion itself, but of an alternative explanation associated with the cortical lesion. From a hodological perspective, the possibility of the associated disconnection of a white matter tract—like Broca’s famous patient—can be evoked. Under this hypothesis, it is no longer the responsibility of a cortical lesion that would be considered, but that of the whole formed by this damaged cortical area and a white matter bundle associated with it. As an example, this approach seems to be quite congruent when it comes to the inferior frontal gyrus as identified by Aron [20, 57]. For each cortical lesion it is thus possible to propose candidate bundles. Finally, in view of the proven functional importance of each of the abovementioned bundles, it will be possible to examine which aspect of the executive functions could be affected: either directly (e.g., by impairment of working memory, or attention), or indirectly (e.g., a slower verbal flow, resulting in longer response times). Alexander loops describe cortical-subcortical networks including frontal areas [58]. These five loops carry a variety of functional meanings, some of which are likely to find a place in the neurobiological bases of executive functions. This raises the question of which of the Alexander loops the cortical areas identified in these studies fall within. All the more so since, for example, the unique target of the “lateral fronto-orbital circuit” loop is precisely the lateral frontal-orbital cortex.
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Table 16.1 Studies mapping inhibition deficits to brain lesions locations
First author Lesions Year Cochereau Diffuse 2020 [63] low-grade gliomas
Time from lesion to neuropsychological assessment (latest) Mean 6.5 months
Number of patients 238 patients
Puglisi 2019 [46]
Right frontal gliomas
One month
63 patients
Santillo 2016 [61]
Fronto temporal dementia and supra-nuclear palsy
Non-applicable
21 patients 25 control
Tsuchida, A Cortex 2012 [60]
Bleeding Tumors
Median: 4 years
45 patients 50 control
Picton 2007 [22]
“Focal lesions” Bleedings Tumors Traumas
More than 3.5 months
43 patients 38 control
Aron 2004 [57]
Hematomas Resected meningiomas
Three years
Right- sided lesions: 19 patients and Left- sided lesions: 17 patients and 20 control
Tests Stroop color naming test
Stroop color naming test Hayling test and frontal behavioral inventory Cortical thickness Anisotropy fraction Stroop color naming task Attention shifting task Go-No-go
Task- switching Inhibition measured by stop-signal task
Brain areas involved Left frontal aslant tract Left superior longitudinal fasciculus (SLF II and SLF III) Right inferior fronto-striatal tracts Right Temporo polar— Orbitofrontal cortex/insula/and Uncinate-anterior cingular cortex
LEFT vlPFC damage led to impaired performance on both tasks
– Right anterior cingulate cortex (AB 24 and 32) – Prefrontal ventrolateral cortex (AB 44, 45, 47) – Right IFG (pars opercularis) – Top-down control/left MFG
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Table 16.1 (continued)
First author Lesions Year Aron Hematomas 2003 [20] Resected meningiomas
Drewe 1975 [55]
Various
Time from lesion to neuropsychological assessment (latest) Three years
Three years
Number of patients 18 patients and 16 control 48 patients: 12 FF only, 12 RF only, 12 Non-F R only, 12 Non-FL only
Tests Stop-signal
Go-No-Go
Brain areas involved – Right IFG (pars triangularis)
Worse when “frontal lesions”
At the end of these approaches, one may wonder for each fascicle and each loop whether they would be likely to participate in a “behavioral” (i.e., limbic) or rather “cognitive” (i.e., neocortical) component of inhibition.
16.4.2.1 Interest of These Studies We consider these studies to be important for two reasons. Firstly, they draw the surgeon’s attention to areas functionally at risk—whether this risk was subcortical more than cortical. Second, they stimulate discussion and guide future studies on the neural networks underlying these few epicenters that are flush with the cortical surface, because within a network it is highly likely that not all bundles are equally important. 16.4.2.2 Limitations of These Studies According to the results of the studies by Miyake [1], then Stuss [59], and Tsuchida [60], the interdependence of executive functions does not allow them to be studied in isolation. This seems to us consistent with a hodological approach which, as we can see from the above, quickly leads to networks that necessarily have cortical areas and/or white matter tracts in common. Moreover, in the absence of persistent handicap documented in the literature, there would be, on the sole basis of the results of very specific tests, a surgical risk of “under-treatment.” Another limitation of these studies is that they did not include an assessment of quality of life, as they focused on test performance.
16.4.3 Study Involving Several Cortical Sites per Patient One study evaluated executive functions in patients with neurodegenerative diseases [61]. The authors observed that these patients exhibited simultaneous alterations in cortical thickness measured by MRI of several regions: right parahippocampal
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gyrus, right fronto-orbital cortex, right insula, as well as a decrease in the anisotropy fraction of the right uncinate and right anterior cingulum. And they observed the association of these findings with a loss of inhibition. This unique observation raises several questions. The first is to examine whether the anatomical locations of the different atrophied regions, taken together, correspond to a known network, and whether this network would potentially be involved in a particular aspect of executive functions. If this were the case, this would be a strong argument in favor of the authors of this study’s discovery of an executive- valence network undergoing involution—the alternative hypothesis of a chance association being very weak. The second would be to adopt the same approach for each site as has been proposed for single-site studies, i.e., which clusters are affected in terms of function by such atrophy.
16.4.3.1 Interest of This Study It is striking that all the structures identified have a direct relationship with the “paralimbic belt.” Three cortical structures—parahippocampal gyrus, insula, and fronto-orbital cortex—belong to it. The other two are very closely associated with it: the uncinate fascicle connects to the temporal pole (another paralimbic area) and the anterior cingulum (the cingulate cortex is also a paralimbic area). It can therefore be hypothesized to explain such an anatomical conjunction that these neurodegenerative diseases affect the paralimbic areas. On the other hand, if the “paralimbic belt” itself meets a cyto-architectonic and not a hodological definition, the fact remains that these structures are themselves involved in the limbic networks [62]. This association thus raises the question of the relationship between the limbic system and inhibition. This again refers to Alexander’s loops, and particularly to the “anterior cingulate” loop. But also to the “lateral orbitofrontal circuit” loop, of which the lateral orbitofrontal cortex is the sole target. 16.4.3.2 Limitations of This Study Given the plurality of structures involved in the disease, it is not possible to make a privileged hypothesis as to which epicenters are responsible for impaired inhibition—since, as we have seen, the paralimbic belt is not a network in itself. Moreover, given the neurodegenerative nature of this disease, it is not possible to identify the loss of autonomy specifically in relation to the function being studied.
16.4.4 Studies of Disconnection - Behavior mapping Two studies to date have focused on the relationship between surgically induced structural disconnections in low-grade glioma patients and postoperative inhibition impairment. It turns out that certain subcortical rather than cortical disconnections give rise to permanent inhibition deficits [46, 63]. The former focused exclusively on patients operated from a right frontal low-grade glioma and outlined the implication of the right fronto-striatal connectivity in postoperative worsening in Stroop test performance which is consistent with Aron’s model [31]. Figure 16.1 illustrates
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Fig. 16.1 The effect of resection on Stroop test performances. The effect of resection on behavioral outcome. (a) The change in Stroop performance time in the two groups (iST - intraoperative Stroop Test - and control group) at the different time points. *p = 0.006. (b) Change in performance on the Stroop test in the two groups measured as the difference between postoperative and preoperative test performance. Values >0 indicate postoperative test performance was slower and values